What happens in the brain during sleepwalking?

Sleepwalking occurs during deep sleep when the prefrontal cortex stays asleep, while other brain regions like the motor cortex become active.

How does anesthesia affect consciousness?

Anesthesia reduces brain wave activity, particularly affecting the thalamus, and alters communication between brain regions, rendering patients unconscious.

What is the effect of split-brain surgery?

Split-brain surgery severs the corpus callosum connecting the two hemispheres, which can lead to independent functioning of each hemisphere, affecting coordination and perception.

How did Phineas Gage's brain injury affect him?

Phineas Gage's accident affected his prefrontal cortex, altering his personality and emotional regulation.

Can our sense of control be influenced or manipulated?

Our sense of agency can be manipulated and is affected by unconscious brain processes and external feedback.

What happens in the brain during improvisation?

Improvisation involves deactivating parts of the prefrontal cortex, allowing creative processes to flow without overthinking.

What contributes to our sense of agency?

Your sense of agency involves integrating feedback and signals from various brain processes.

How can trauma affect future generations?

Traumatic experiences can affect genes and be passed to future generations, influencing traits and behaviors.

What influences our decisions and behaviors?

We are influenced by genetics, environment, social interactions, and subconscious processes, not entirely by conscious decisions.

What defines consciousness?

The brain's communication level among regions distinguishes conscious from unconscious states, involving multiple areas working together.

Your Brain: Who's in Control? | Full Documentary | NOVA | PBS

00:53:33

https://www.youtube.com/watch?v=yQ6VOOd73MA

الملخص

TLDRThis video from the "NOVA" series dives into the complexity of the human brain, emphasizing the interplay between conscious and unconscious processes. Various experts discuss how different brain regions contribute to our sense of self and control. Key topics covered include the intricacies of sleepwalking, the effects of anesthesia on consciousness, and insights from split-brain research which demonstrate how disconnected brain hemispheres function independently. The episode further examines how emotions and social contexts influence decision-making, with studies revealing how creativity and improvisation require certain parts of the brain to deactivate. It highlights how unconscious processes often govern our thoughts and behaviors more than we realize. Also, the exploration into intergenerational trauma shows how events can impact not just the individual but also subsequent generations. The documentary ultimately questions how much control and agency we truly possess, suggesting that much of our sense of self is an illusion created by various brain functions acting in concert.

الوجبات الجاهزة

🧠 The brain is responsible for our entire perception of self and identity.
💤 Sleepwalking illustrates the complexity of unconscious control over actions.
💉 Anesthesia disrupts brain communication, inducing unconsciousness.
🔀 Split-brain studies show how different brain parts can operate independently.
🔑 Emotions significantly influence our decision-making processes.
🧬 Traumatic experiences can have transgenerational impacts.
🤔 Agency perception can be manipulated by experimental setups.
🎨 Creativity often involves letting go of conscious control.
🎭 Our behavior is heavily influenced by social interactions.
🔍 Uncovering unconscious processes can lead to greater self-awareness.

الجدول الزمني

00:00:00 - 00:05:00
The episode introduces the central theme: the mystery of the brain and its role in personality, thoughts, and feelings. Scientists discuss the perception of control over our actions and how our brain functions might suggest a different reality. Sleepwalking and cases of split-brain patients illustrate how complex actions can occur unconsciously, raising questions about consciousness and the self.
00:05:00 - 00:10:00
Heather Berlin visits a sleep center to learn about sleepwalking. It involves complex behaviors done unconsciously, as evidenced by brainwave monitoring during sleep. Sleepwalking illustrates the brain's capability to execute intricate tasks without conscious awareness, as the prefrontal cortex remains inactive while other regions act independently, supporting the notion that consciousness isn't absolute.
00:10:00 - 00:15:00
The discussion shifts to consciousness levels during anesthesia, where brain activity is highly reduced. Similar to sleepwalking, it highlights how unconscious processes still operate. Visual experiments with split-brain patients show how the brain manages independent actions separately, further questioning the unified sense of self and opening ideas of multiple cognitive entities within an individual.
00:15:00 - 00:20:00
The show explores how emotional and social environments shape our brain processes and decision-making. Through Trust Game experiments, it reveals the insula's role in feeling guilt and making cooperative decisions. Emotions are shown to enhance decision quality, balancing self-interest with social behavior, emphasizing the brain's integration of complex emotional feedback loops.
00:20:00 - 00:25:00
The narrative continues with Phineas Gage's story, illustrating how damage to the prefrontal cortex significantly affects behavior and emotions. This underscores how specific brain regions contribute to personality and moral judgment. Emotion's role in rational decision-making is re-evaluated, suggesting emotions play a crucial part in determining our actions and interactions.
00:25:00 - 00:30:00
The focus shifts to how trauma and the environment can influence genetic expression across generations. Research into generational impacts of trauma, such as famine, shows shifts in gene expression, implicating a biological basis for how experiences can shape future generations. This questions our understanding of inherited traits and environmental adaptability in humans.
00:30:00 - 00:35:00
The episode then questions the concept of agency through experiments that show how easily our sense of control can be manipulated. It demonstrates through TMS experiments that perceived voluntary action can be influenced, suggesting that agency is a complex interplay of conscious and unconscious processes. This challenges our certainty about being the sole authors of our actions.
00:35:00 - 00:40:00
The show highlights creativity and improvisation as examples of letting go of conscious control for enhanced performance. Through brain scans of freestyle rappers, it shows how the prefrontal cortex's deactivation during improvisation allows for uninhibited creativity, suggesting that less conscious interference can lead to better performance in creative tasks.
00:40:00 - 00:45:00
A deeper dive into unconscious influence reveals that being unaware of certain processes doesn't lessen their impact. Discussions touch on how cultural, genetic, and social factors silently shape behaviors and decisions. This introduces the perspective that much of what makes us 'us' operates below conscious perception, acknowledging the nuanced complexities of identity.
00:45:00 - 00:53:33
The closing remarks tie together the insights about unconscious processes, brain function, and identity. It emphasizes the brain's role in shaping our experience of self, which is not entirely under conscious control. By understanding the unconscious parts, individuals can gain better insight into their behaviors and perhaps find a way to navigate and possibly influence these underlying processes.

اعرض المزيد

الخريطة الذهنية

فيديو أسئلة وأجوبة

What happens in the brain during sleepwalking?
Sleepwalking occurs during deep sleep when the prefrontal cortex stays asleep, while other brain regions like the motor cortex become active.
How does anesthesia affect consciousness?
Anesthesia reduces brain wave activity, particularly affecting the thalamus, and alters communication between brain regions, rendering patients unconscious.
What is the effect of split-brain surgery?
Split-brain surgery severs the corpus callosum connecting the two hemispheres, which can lead to independent functioning of each hemisphere, affecting coordination and perception.
How did Phineas Gage's brain injury affect him?
Phineas Gage's accident affected his prefrontal cortex, altering his personality and emotional regulation.
Can our sense of control be influenced or manipulated?
Our sense of agency can be manipulated and is affected by unconscious brain processes and external feedback.
What happens in the brain during improvisation?
Improvisation involves deactivating parts of the prefrontal cortex, allowing creative processes to flow without overthinking.
What contributes to our sense of agency?
Your sense of agency involves integrating feedback and signals from various brain processes.
How can trauma affect future generations?
Traumatic experiences can affect genes and be passed to future generations, influencing traits and behaviors.
What influences our decisions and behaviors?
We are influenced by genetics, environment, social interactions, and subconscious processes, not entirely by conscious decisions.
What defines consciousness?
The brain's communication level among regions distinguishes conscious from unconscious states, involving multiple areas working together.

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الترجمات

التمرير التلقائي:

00:00:01
♪ ♪
00:00:06
SUSANA MARTINEZ-CONDE: The brain is the biggest mystery in science today.
00:00:10
THALIA WHEATLEY: It's responsible for all the facets of our personality,
00:00:14
everything we think and everything we feel.
00:00:16
It makes you you.
00:00:18
URI MAOZ: A very large fraction
00:00:20
of what's happening in my brain I am not aware of at all.
00:00:24
HEATHER BERLIN: But what exactly is going on in your unconscious brain?
00:00:27
What part of your brain is really in charge?
00:00:30
CHARLES LIMB: All day long, we're doing
00:00:32
unscripted things that we didn't know we would be doing.
00:00:34
(sizzling)
00:00:35
Life is not scripted.
00:00:37
MAOZ: Find a word that has some meaning for you.
00:00:40
BERLIN: So you might think you've made a choice...
00:00:42
Representation.
00:00:44
BERLIN: But in the back of your mind, you wonder...
00:00:46
Come on!
00:00:48
BERLIN: Was that really me?
00:00:49
♪ ♪
00:00:51
We might feel like we're in control.
00:00:54
ANIL SETH: This idea that we're in control of our actions
00:00:56
seems critical to our sense of identity.
00:00:59
BERLIN: But our brains may have other ideas.
00:01:02
BOBBY KASTHURI: The brain is made of almost 90 billion neurons,
00:01:05
but it produces this illusion
00:01:07
that there's a single person inside our skulls.
00:01:11
LUKE CHANG: For every Pinocchio, there's always someone
00:01:13
kind of pulling the strings behind the scenes.
00:01:15
(device beeps)
00:01:16
♪ ♪
00:01:18
MICHAEL GAZZANIGA: There can be two separated minds inside one system.
00:01:22
WHEATLEY: It's not just that motor,
00:01:24
memory, language is in the brain.
00:01:26
Your personality is up there,
00:01:27
your morality is up there.
00:01:30
BIANCA JONES MARLIN: We as humans know how environment and traumatic events
00:01:34
change people.
00:01:36
BERLIN: "Your Brain: Who's In Control?"
00:01:39
Right now, on "NOVA."
00:01:42
♪ ♪
00:01:55
BERLIN: Have you ever thought that you've made
00:01:57
a crystal-clear decision?
00:01:59
(inner voice): I'm just gonna watch two episodes tonight.
00:02:01
(narration): But the next thing you know...
00:02:04
(inner voice): Okay, just one more episode.
00:02:05
(laugh track playing)
00:02:08
Actually, it's time to go to bed.
00:02:09
♪ ♪
00:02:11
Well, I bet everyone else has already finished this season.
00:02:13
(static hissing, laugh track plays)
00:02:14
Wait, why am I still watching this?
00:02:16
(narration): Well, of course, the answer lies in
00:02:19
your brain.
00:02:21
♪ ♪
00:02:22
Your brain contains multitudes.
00:02:25
It's a complex and intricate three-pound piece of matter.
00:02:30
But you actually have no awareness
00:02:32
of most of the things that are going on
00:02:33
inside your brain.
00:02:35
I'm neuroscientist and clinical psychologist Heather Berlin.
00:02:40
(laughs)
00:02:40
Come on, man!
00:02:43
BERLIN: And I'm on a journey to discover
00:02:46
what's really driving the decisions you make?
00:02:48
(device clicks)
00:02:49
No agency at all.
00:02:52
Who or what is really in control?
00:02:55
There are important unconscious processes
00:02:58
in your brain that you're not aware of.
00:02:59
Most of the time, the brain is a coordinated,
00:03:02
well-oiled machine, with different brain regions
00:03:05
working together in harmony.
00:03:08
(audio distorting): But under certain circumstances,
00:03:10
when things are out of sync,
00:03:11
we can gain deeper insight
00:03:13
into how the brain actually works.
00:03:17
(wildlife chirping)
00:03:20
♪ ♪
00:03:28
There's one thing we do every day
00:03:29
with little to no conscious control.
00:03:31
It's something you might spend a whole third of your life doing:
00:03:35
sleeping.
00:03:36
When we sleep, we're supposed to be unconscious and at rest.
00:03:41
But for some people, that's not always the case.
00:03:46
♪ ♪
00:03:50
(mumbling)
00:03:52
BERLIN: These are people who sleepwalk.
00:03:54
MAN: Just like, just like you were?
00:03:56
EMMANUEL DURING: Sleepwalking is a glitch
00:03:57
in the system,
00:03:59
because our identity is not in control.
00:04:01
And that's what a lot of my patients
00:04:05
tell me, like, they, "I didn't do that.
00:04:07
"That's not possible.
00:04:10
This is not me."
00:04:11
♪ ♪
00:04:19
So, sleepwalking?
00:04:20
Very common condition or phenomenon.
00:04:22
Simply said, it's what the word is.
00:04:24
You sleep,
00:04:26
but during your sleep, you will walk.
00:04:29
We take it for granted, right?
00:04:31
But the walking is extremely complex.
00:04:32
Just teaching a robot
00:04:35
all the inputs and outputs for a body
00:04:39
to move forward on two legs without falling.
00:04:44
All of this, you don't even think about it.
00:04:47
It works independently.
00:04:50
♪ ♪
00:04:52
BERLIN: How is it possible to do complex behaviors like walking,
00:04:55
eating, and sometimes even driving while sleeping?
00:05:00
♪ ♪
00:05:01
To find out, I'm visiting a sleep center
00:05:03
at the Icahn School of Medicine at Mount Sinai.
00:05:06
So, tell me a little bit
00:05:08
about what's happening with you at night
00:05:10
and your sleepwalking.
00:05:12
Well, I've been doing some weird things.
00:05:15
I painted a wall in my living room
00:05:16
and one in my kitchen.
00:05:18
I made a triangle, a perfect triangle...
00:05:20
What?
00:05:20
...in my kitchen.
00:05:21
So what do you think
00:05:22
when you find that?
00:05:24
Like...
00:05:24
I don't know.
00:05:25
Just-- I laugh, because I go,
00:05:26
"How the heck I did this?"
00:05:29
BERLIN: Emmanuel During studies what's going on in the brain
00:05:32
when someone sleepwalks.
00:05:33
In the center, sleep patients are wired up with sensors
00:05:36
that pick up eye and body movements--
00:05:39
as well as their brain waves-- while they sleep.
00:05:43
So what are we looking at here,
00:05:44
these blue lines?
00:05:45
DURING: These are the eye movements.
00:05:47
Okay, and then the, the black lines here?
00:05:49
These are the brain waves.
00:05:50
So this patient is obviously,
00:05:51
he's lying in bed.
00:05:52
Mm-hmm.
00:05:54
And dozes off slowly, feels sleepy.
00:05:57
And as we move on, he dives into
00:05:59
deep slow-wave sleep.
00:06:01
BERLIN: During sleep, your brain
00:06:03
cycles through phases of high and low activity.
00:06:07
When the brain waves slow down,
00:06:09
scientists call this "deep sleep."
00:06:11
But when someone sleepwalks...
00:06:14
First of all, everything looks good.
00:06:17
You see the brainwaves.
00:06:17
Mm-hmm.
00:06:20
Everything is very, very monotonous,
00:06:22
sort of slow waves.
00:06:22
Mm-hmm.
00:06:24
And then it's interesting,
00:06:25
since there's a buildup of slow wave,
00:06:27
that the amplitude goes up,
00:06:29
and then suddenly...
00:06:31
Whoa.
00:06:31
So he's seemingly awake.
00:06:33
Sudden.
00:06:33
Yeah.
00:06:34
Looks like a sudden arousal.
00:06:37
Looks sort of scared.
00:06:37
I mean, very brief.
00:06:39
Very fast, eyes open.
00:06:40
There's a, sort of a split, then.
00:06:43
BERLIN: The patient looks like they're awake.
00:06:46
But a couple of key brain regions seem to stay asleep.
00:06:50
DURING: There's part of the brain stays in slow-wave sleep.
00:06:53
It's such a deep stage of, of sleep, it's hard to wake up,
00:06:56
and the other part of the brain is already awake.
00:06:58
BERLIN: One part of the brain that doesn't wake up during
00:07:01
sleepwalking is called the prefrontal cortex.
00:07:04
It's the region of the brain responsible for
00:07:06
deliberate choices and self-awareness.
00:07:09
DURING: This prefrontal cortex is the decision maker.
00:07:13
The other areas of the brain
00:07:15
can mostly work independently of that.
00:07:18
♪ ♪
00:07:20
So, essentially, so many parts of the brain
00:07:22
can be engaged without conscious awareness of it.
00:07:26
BERLIN: During sleepwalking, the motor cortex,
00:07:29
which controls movement, the visual cortex,
00:07:32
which processes visual information,
00:07:34
and the parts of the brain
00:07:35
that coordinate behaviors like balance and speech
00:07:38
can all become active
00:07:39
without engaging the prefrontal cortex.
00:07:43
MAN: And what exactly are you doing, ma'am?
00:07:45
It's a special code.
00:07:49
MARTINEZ-CONDE: Experiences of sleepwalking reveal that being conscious
00:07:53
is not an all-or-none situation.
00:07:56
Our unconscious makes a lot of everyday decisions for us.
00:08:01
NANCY KANWISHER: For starters, boring stuff,
00:08:04
like regulating your heart rate and your temperature
00:08:06
and deciding when to take the food in your stomach
00:08:08
and move it down into your gut.
00:08:10
Like, thank God we don't have to be aware of all that stuff.
00:08:13
DANIELA SCHILLER: Motor function, sensory function,
00:08:16
motor-sensory integration,
00:08:17
memory representation.
00:08:19
All of this is happening
00:08:20
below the surface, like the inside of a clockwork.
00:08:25
(man mumbling)
00:08:25
BERLIN: When you sleepwalk,
00:08:29
the brain regions that control your movement, vision,
00:08:31
and breathing can get up to all kinds of mischief
00:08:34
without you even knowing it.
00:08:36
But there's one case where even those regions check out--
00:08:40
during anesthesia.
00:08:42
♪ ♪
00:08:44
We know that there are drugs
00:08:45
that I can give you, anesthetics,
00:08:46
that would remove your conscious experience.
00:08:50
SETH: And we all know that consciousness comes in degrees.
00:08:53
Like, we can lose consciousness in sleep,
00:08:55
but then we lose it in a more profound way
00:08:57
when we are under general anesthesia.
00:09:01
BERLIN: When I was a young researcher working in anesthesiology,
00:09:04
I saw this firsthand.
00:09:06
So what happens to your brain activity when you go under?
00:09:11
♪ ♪
00:09:17
Neuroscientist Emery Brown is measuring the line
00:09:19
that separates being conscious
00:09:21
from being unconscious.
00:09:24
BROWN: I want to guarantee my patients
00:09:26
that when I say you're unconscious,
00:09:27
you're not going to perceive pain,
00:09:29
you won't be moving around,
00:09:31
you won't remember anything that's occurring.
00:09:33
Your heart rate and blood pressure
00:09:35
and other physiological systems will be well-controlled.
00:09:36
♪ ♪
00:09:41
BERLIN: The patient is undergoing surgery.
00:09:44
But before the surgeons can operate,
00:09:46
the anesthesiologists have to put her under--
00:09:48
render her unconscious with special drugs.
00:09:52
WOMAN: I'm starting to give you medicines
00:09:53
that might make you feel kind of drowsy.
00:09:55
BROWN: Look straight ahead.
00:09:57
Look straight ahead.
00:09:58
See, her eyes move
00:10:00
as we expect them to move.
00:10:01
So you're moving her head, but her eyes stay straight.
00:10:03
WOMAN: All right, now we're going to have you breathe
00:10:05
a little oxygen.
00:10:05
BROWN: Breathe some oxygen for a minute.
00:10:07
And can you see my finger here?
00:10:09
Follow it with your eyes.
00:10:12
And if you can't follow it anymore, tell me, all right?
00:10:17
Can you hear me?
00:10:18
♪ ♪
00:10:21
See her eyes are fixed now?
00:10:21
BERLIN: Yeah.
00:10:23
You see the E.E.G. has a large, slow oscillation?
00:10:26
See that?
00:10:26
BERLIN: Yeah, yeah.
00:10:27
BROWN: Her brain stem is out.
00:10:29
BERLIN: It's out, that's it?
00:10:29
BROWN: Mm-hmm.
00:10:31
BERLIN: When you go under, it can feel like
00:10:34
one second you're here, and the next,
00:10:36
you're out.
00:10:39
What's going on in the brain when this happens?
00:10:42
Emery uses a device called an E.E.G.,
00:10:47
a set of electrodes that rests on the scalp
00:10:49
and detects electrical activity in the brain.
00:10:52
That activity comes in the form of waves.
00:10:56
BROWN: The brain generates brain waves or oscillations.
00:11:00
And there are oscillations
00:11:01
that we typically see when someone's conscious.
00:11:04
BERLIN: These brain waves are measured by their frequency,
00:11:07
how fast the waves come and go,
00:11:09
and by their amplitude, how small or big the waves are.
00:11:13
BROWN: I look at your E.E.G.
00:11:14
When you're awake,
00:11:16
you're going to have a very rich response.
00:11:18
When I anesthetize you, it goes away.
00:11:21
And so the difference between those two states
00:11:23
represents the transition from being conscious
00:11:25
to the unconscious.
00:11:27
See the oscillations, see how they're
00:11:28
really big now.
00:11:28
BERLIN: Yeah.
00:11:29
And before, see, they were just sort of little...
00:11:31
Yeah, exactly.
00:11:31
Kind of, yeah.
00:11:32
(talking in background)
00:11:35
BERLIN: When you're awake and fully aware,
00:11:37
your brain wave activity is diverse and dynamic.
00:11:41
It looks kind of like an exciting conversation.
00:11:44
But when anesthesia drugs hit the brain,
00:11:49
the activity is dramatically reduced
00:11:52
to dull, slow-rolling brain waves.
00:11:55
The once dynamic conversation
00:11:57
becomes an unintelligible hum.
00:12:00
BROWN: If you alter how
00:12:01
the parts of the brain communicate sufficiently,
00:12:03
you can make someone unconscious.
00:12:04
So that's what the drugs are doing.
00:12:07
They're altering the way
00:12:08
the various parts of the brain communicate.
00:12:11
BERLIN: There's one region of the brain in particular that acts as
00:12:15
a communication hub: the thalamus.
00:12:18
It's made up of two parts, each about the size of a walnut,
00:12:21
and sits deep inside your brain.
00:12:24
BROWN: Thalamus is a central way station
00:12:26
for all sorts of information processing.
00:12:28
Auditory information goes through there,
00:12:30
visual information goes through there,
00:12:32
pain information goes through there.
00:12:35
If I could take out
00:12:37
just one brain center to make you unconscious,
00:12:38
it would probably be the thalamus,
00:12:40
because it's such a central actor
00:12:42
in processing all types of information.
00:12:45
BERLIN: After a couple of hours of surgery,
00:12:47
the medical team is tapering off the anesthesia drugs.
00:12:51
And the E.E.G. reveals the patient's brain wave activity
00:12:56
becoming more complex as she wakes up.
00:12:58
ANTHONY: She's starting to take
00:13:00
some breaths on her own.
00:13:00
BROWN: Yeah.
00:13:01
ANTHONY: Open your eyes wide.
00:13:03
And squeeze my hand.
00:13:05
BROWN: Consciousness is really having active cognitive processing,
00:13:09
being able to think and act.
00:13:10
ANTHONY: Surgery's all done, okay?
00:13:12
BROWN: It's the integration of that information
00:13:13
which allows us to start to understand
00:13:16
how consciousness is actually formed.
00:13:21
♪ ♪
00:13:22
KASTHURI: Consciousness can obviously
00:13:24
interact with the physical world like we can.
00:13:26
We can use drugs to remove it.
00:13:28
We go to sleep and we're not conscious, and yet,
00:13:31
it's tenuous at the same time.
00:13:33
We can't say how any specific set of neurons
00:13:36
working together produces consciousness.
00:13:39
REBECCA SAXE: It's so clear that anesthesia
00:13:41
is some kind of change of consciousness, right?
00:13:44
The whole brain is there, the pieces are there,
00:13:48
but the messages aren't getting through
00:13:50
in a way that makes for our conscious experience.
00:13:52
(static hissing, beeps distorting)
00:13:53
And that's the difference between
00:13:55
being aware and not being aware.
00:13:58
BERLIN: So the level of communication
00:14:00
among brain regions is one difference
00:14:02
between being conscious and being unconscious.
00:14:05
That means that no single area of the brain
00:14:10
is responsible for your consciousness.
00:14:13
It's that communication that helps make you you.
00:14:17
MAN: Now, let's remember that the left hand
00:14:20
is governed from the right hemisphere.
00:14:22
BERLIN: For some people, an entire half of their brain
00:14:25
can't really communicate with the rest.
00:14:28
These are people who have undergone split-brain surgery,
00:14:32
and it's as if...
00:14:34
(audio doubled): They have two minds in a single brain.
00:14:38
MAN: Now the question becomes,
00:14:39
what happens when you allow
00:14:41
both hands together to try to solve the problem?
00:14:43
And what we find out is that they fight over each other.
00:14:45
One hand knows how to do it and one hand does not,
00:14:48
and so they more or less squabble.
00:14:51
The human brain contains two sides,
00:14:53
the left hemisphere and the right hemisphere, right?
00:14:55
And they are connected by a big bundle of fibers.
00:14:58
It's called the corpus callosum.
00:15:00
All the communication from one side of the brain
00:15:03
to the other has to pass through this fiber bundle.
00:15:07
BERLIN: For some people with epilepsy, a seizure in one hemisphere
00:15:11
can quickly spread to the other by way of the corpus callosum.
00:15:16
But if that bridge is surgically severed,
00:15:19
a seizure can no longer cross to the other side of the brain.
00:15:23
In addition to treating epilepsy,
00:15:25
these surgeries have also led
00:15:27
to some astounding research into
00:15:29
how the two hemispheres function.
00:15:32
MILLER: With your left hand, make me the a-okay sign.
00:15:35
(woman laughs)
00:15:36
BERLIN: To learn more about these fascinating studies,
00:15:40
I met two pioneers in the field:
00:15:42
Michael Miller
00:15:44
and Michael Gazzaniga.
00:15:46
Michael Miller asked me
00:15:49
to step into his lab to do a few simple tests,
00:15:52
just like the ones he's conducted with patients
00:15:55
after split-brain surgery.
00:15:56
So, Heather, what you're going to see
00:15:58
are two shapes.
00:15:59
They're going to come up on the screen.
00:16:01
♪ ♪
00:16:03
You're gonna draw the shape on the left side of the screen
00:16:05
with your left hand,
00:16:06
and the shape on the right side of the screen
00:16:07
with your right hand.
00:16:09
And I want you to draw them as quickly as you can
00:16:11
at the same time.
00:16:13
Okay?
00:16:13
(laughs): Okay.
00:16:14
BERLIN: Piece of cake, right?
00:16:16
(device beeps)
00:16:19
Oh...
00:16:19
MILLER: Beautiful.
00:16:20
(laughs)
00:16:24
Okay, not sure what you were drawing over here, but...
00:16:25
(laughs)
00:16:27
(device beeps)
00:16:29
Oh. (chuckles)
00:16:29
(laughing): Okay.
00:16:31
Did I mention I didn't get that much sleep last night?
00:16:32
(laughs)
00:16:35
BERLIN: The left side of the brain
00:16:37
controls most of the right side of the body.
00:16:39
And the right side of the brain
00:16:41
controls most of the left side of the body.
00:16:45
(all laughing)
00:16:46
What happened is, I started out trying to do different things,
00:16:48
and then they just sort of, like, sync up together.
00:16:48
MILLER: Yeah, yeah.
00:16:50
♪ ♪
00:16:52
(laughs)
00:16:52
Come on, man.
00:16:53
MILLER: It's perfectly normal.
00:16:55
So, I mean, what's happening is that the motor commands
00:16:58
in the, in one hemisphere...
00:16:58
Right.
00:17:00
...are interfering with the motor commands
00:17:01
in the other hemisphere.
00:17:03
BERLIN: It was basically impossible
00:17:06
for me to force my hands
00:17:07
to draw two different things at the same time.
00:17:12
But for someone whose two hemispheres
00:17:13
are disconnected, there's no interference.
00:17:17
It's almost as if there's one mind
00:17:19
controlling the left hand,
00:17:21
and a completely different mind controlling the right hand.
00:17:24
And it isn't just movement
00:17:26
that's split across the hemispheres.
00:17:28
Only half of your visual field goes to each side of the brain.
00:17:33
MILLER: When you're looking straight ahead,
00:17:35
everything to the left side of that space
00:17:38
goes only to the right hemisphere.
00:17:41
And the opposite is true for the right side of the space.
00:17:44
GAZZANIGA: The left part of the brain is where your language
00:17:48
and speech centers are.
00:17:49
That enables you to talk,
00:17:51
enables you to understand language, and all the rest.
00:17:54
And the right side of your brain
00:17:56
is very important in the evaluation of emotions,
00:17:59
evaluation of visual space.
00:18:03
I'm going to give you a test.
00:18:05
MAN: If you look right at my nose,
00:18:07
I'm going to hold up my hands.
00:18:09
You tell me how many fingers you see, all right?
00:18:11
GAZZANIGA: How many fingers do you see?
00:18:13
You see two, right?
00:18:15
Why did you see two?
00:18:17
(chuckling): This one went to your left hemisphere,
00:18:21
this one went to your right hemisphere,
00:18:23
way over in the other side of your brain.
00:18:25
How does your left hemisphere know about it?
00:18:27
That pathway, the corpus callosum.
00:18:30
It transfers that information.
00:18:32
Now I'm going to split your brain,
00:18:35
and I do the same test.
00:18:36
How many fingers do I see?
00:18:40
WOMAN: Two.
00:18:41
You see anything else?
00:18:45
No.
00:18:46
Okay.
00:18:48
You see one, you see this one,
00:18:50
because that goes straight to your left, talking hemisphere.
00:18:54
This one is still going to your right hemisphere,
00:18:57
which has now been disconnected from your left.
00:19:01
So your left brain can't talk about this.
00:19:04
So you now say you only see one finger,
00:19:06
even though your right brain is seeing this finger.
00:19:10
It just can't talk about it,
00:19:13
because the highway that communicates that information
00:19:16
has been cut.
00:19:17
Show me with your right hand what you see.
00:19:20
Two.
00:19:20
Okay.
00:19:22
Put it down, relax.
00:19:25
Show me with your left hand what you see.
00:19:29
One.
00:19:29
Good.
00:19:31
MILLER: It's the most remarkable thing to witness.
00:19:34
You know, there's this whole other entity
00:19:36
in the head that's controlling the body
00:19:39
and can understand and remember
00:19:41
and feel and think all on its own,
00:19:43
completely separate from the other side.
00:19:47
BERLIN: The researchers conducted tests
00:19:49
to explore how a split-brain patient's
00:19:52
two hemispheres work independently
00:19:54
from one another--
00:19:56
including a now-famous experiment
00:19:58
of a patient named Joe.
00:19:59
GAZZANIGA: Look right at the dot.
00:20:02
BERLIN: By quickly flashing a word
00:20:04
to just the left side of his visual field...
00:20:06
(device beeps)
00:20:06
GAZZANIGA: See anything?
00:20:08
BERLIN: ...that word would go exclusively
00:20:09
to the right half of his brain,
00:20:11
the half that can't talk.
00:20:14
So the only way we're going to know that it registered
00:20:16
is if he can write something out, okay?
00:20:19
With his hand that is controlled by his right hemisphere.
00:20:22
Exactly, his left hand.
00:20:22
The left hand.
00:20:24
GAZZANIGA: We flash the word "Texas."
00:20:26
GAZZANIGA: Look right at the dot.
00:20:28
See anything?
00:20:29
There's a flash.
00:20:29
All right.
00:20:31
I didn't see the word.
00:20:33
His right hemisphere is seeing it.
00:20:36
GAZZANIGA: We're seeing it, but the right hemisphere,
00:20:38
at this point in his surgery,
00:20:41
cannot talk.
00:20:41
Right.
00:20:43
GAZZANIGA: All right, I want you to draw for me that thing
00:20:49
upside down.
00:20:51
BERLIN: So he claims to not have seen anything.
00:20:54
Yeah.
00:20:54
Oh, my God.
00:20:56
(laughs)
00:20:56
Wow.
00:20:57
BERLIN: He was able to do Texas upside down.
00:20:57
GAZZANIGA: Yeah.
00:21:00
MILLER: But what's interesting is, he had no idea what he's drawing.
00:21:03
MILLER: We know because we saw the word.
00:21:04
JOE (chuckling): I can't tell what it is.
00:21:06
BERLIN: Wow.
00:21:08
GAZZANIGA: So then, later on, I show him the word again
00:21:10
and I ask a different question
00:21:11
about what he saw.
00:21:14
BERLIN: Once again, they showed the word "Texas"
00:21:16
to just his right, non-verbal hemisphere.
00:21:19
So when asked about what he saw,
00:21:21
all his left hemisphere can say is...
00:21:24
I'm aware of a word, I just didn't see what it was.
00:21:27
GAZZANIGA (in video): Draw something that goes with that.
00:21:30
A symbol of that.
00:21:34
BERLIN: Oh, wow,
00:21:36
so he draws a cowboy hat.
00:21:36
MILLER: Yeah, clearly...
00:21:37
Yeah, clearly, his right hemisphere
00:21:38
knows exactly what he's drawing.
00:21:38
Wow.
00:21:40
But his left is still confused,
00:21:43
so he doesn't understand it.
00:21:43
Right.
00:21:44
GAZZANIGA: What's that?
00:21:46
Cowboy hat.
00:21:48
Cowboy hat?
00:21:49
What was the word?
00:21:51
(whispering): So amazing.
00:21:51
JOE (in video): Texas.
00:21:52
(laughing): I can't believe it.
00:21:54
GAZZANIGA: Did you see "Texas"?
00:21:54
No.
00:21:57
GAZZANIGA: The split-brain phenomenon suggests that there can be
00:22:01
two separated minds, if you will,
00:22:03
inside of a skull.
00:22:05
The cooperation is on the paper, not inside the head.
00:22:09
It's an astounding example
00:22:11
of cross-cueing and management of two mental systems
00:22:15
into one unified act.
00:22:17
And the idea is
00:22:19
maybe that's going on in us all the time, too.
00:22:24
KANWISHER: Each of us has a sense that we're a unitary being,
00:22:27
but actually, that belies the fact
00:22:29
that each of us, each of our minds,
00:22:31
is actually composed of lots of different pieces
00:22:33
that are doing different things.
00:22:34
And different information can be represented
00:22:36
in different parts of that machinery.
00:22:39
And so a search for "where am I in all of this?"
00:22:43
is a little bit misguided,
00:22:44
because the "I" is not
00:22:46
such a unitary thing in the first place.
00:22:48
KASTHURI: That feeling of unity, of "me," is actually distributed
00:22:53
across almost 90 billion neurons.
00:22:56
This illusion that there's a single person
00:23:00
inside our skulls.
00:23:01
♪ ♪
00:23:03
BERLIN: Inside your brain are over 100 distinct regions.
00:23:07
Many different systems in the brain
00:23:09
control what you do, from movement,
00:23:11
to vision, to speech, and even social interaction.
00:23:17
MAHZARIN BANAJI: I think most human beings like to believe
00:23:19
that their mind is under their own control.
00:23:22
If I want to, I can stand up right now.
00:23:25
I can do that.
00:23:26
And that gives me, I think, the false belief
00:23:30
that everything I do has been chosen by me.
00:23:33
And if there is a story from the brain to tell,
00:23:35
it is that we are quite wrong.
00:23:37
BERLIN: Not only are there multiple parts
00:23:39
of your brain influencing you,
00:23:42
but there are things in the world around you
00:23:43
that influence your brain,
00:23:46
including other people.
00:23:48
SAXE: How we act and who we are in our lives
00:23:51
is hugely determined by
00:23:54
the expectations of the people around us.
00:23:56
The brain helps us be the most social species on the planet.
00:24:00
A lot of our brains are devoted to understanding other people.
00:24:04
SCHILLER: Our brain doesn't operate in isolation.
00:24:08
We constantly learn, take, compare to other brains.
00:24:12
CHANG: Our brains have evolved to be able to
00:24:15
effortlessly reason about other people.
00:24:18
And emotions, similarly, have evolved
00:24:20
as ways that guide our behavior.
00:24:22
BERLIN: So, how exactly do emotions--
00:24:26
and the emotions of others-- influence our brains?
00:24:31
Neuroscientist Luke Chang studies how
00:24:33
emotions like greed and guilt affect our decision-making.
00:24:37
MAN: Hey, Grace, we're going to start up the scout.
00:24:39
GRACE (on speaker): Okay.
00:24:41
Go ahead and make your decision.
00:24:44
(softly): Okay, did you tell her to go on to the next one?
00:24:45
MAN: Yep, you can hit next.
00:24:48
BERLIN: So, what are you guys looking at here?
00:24:50
What's this study about? Is there...
00:24:52
So she's playing an investment game...
00:24:54
Okay.
00:24:54
...with another participant,
00:24:55
who's outside the scanner.
00:24:57
BERLIN: Luke scans the brains of study participants
00:25:01
while they play a game from behavioral economics
00:25:04
called the Trust Game.
00:25:07
CHANG: This is a cooperative game
00:25:08
where one person has some sum of money,
00:25:11
and they can choose to invest any amount of that money
00:25:13
in their partner.
00:25:14
BERLIN: That investment grows.
00:25:17
So then, the study participant has to decide:
00:25:22
they could be greedy and keep all the money
00:25:25
or they could be generous,
00:25:27
and give some of the investment back.
00:25:29
♪ ♪
00:25:31
CHANG: We've always been really interested in,
00:25:33
why do people return the money when they don't have to?
00:25:36
And guilt provides one plausible mechanism
00:25:39
that might be driving their behavior
00:25:41
to act cooperatively in this game.
00:25:44
BERLIN: And so you're balancing making these decisions
00:25:46
between getting that kind of dopamine reward hit
00:25:50
from being a little selfish
00:25:52
versus being balanced by those feelings of, maybe, guilt
00:25:56
when you're not cooperating or helping somebody else out.
00:26:00
BERLIN: And the brain scans reveal which parts of the brain
00:26:03
are most active when someone is feeling guilt.
00:26:07
CHANG: Those regions ended up being
00:26:08
something called the insula.
00:26:09
Signals about having this gut feeling
00:26:12
that maybe this isn't a good idea,
00:26:14
or, "I'd feel really bad if I did that."
00:26:16
Those are the signals that originate from the insula
00:26:18
that allow us to make decisions to avoid harming someone else.
00:26:21
♪ ♪
00:26:24
BERLIN: Luke likes to think of it kind of like a thermometer
00:26:26
and a thermostat.
00:26:28
CHANG: If you try to think about how
00:26:29
a thermostat might be mapped onto the brain,
00:26:31
one region might be more like the thermometer,
00:26:34
detecting the ambient temperature in the room.
00:26:37
BERLIN: When it comes to reading the room,
00:26:39
our brain's thermometer seems to be the insula.
00:26:43
But all that information needs to go somewhere else
00:26:46
and be integrated with other types of information.
00:26:48
BERLIN: That's our brain's thermostat--
00:26:51
a region located inside the prefrontal cortex
00:26:53
that processes our emotions and helps regulate our behavior.
00:26:58
And while your thermostat can usually help you
00:27:00
take control of your emotions,
00:27:02
what would happen if it went out?
00:27:06
♪ ♪
00:27:08
CHANG: There's a famous patient named Phineas Gage.
00:27:11
WHEATLEY: Phineas Gage was a railroad foreman
00:27:13
who was working in Vermont,
00:27:15
and he was tamping down a hole that had gunpowder in it,
00:27:21
and the gunpowder ignited,
00:27:22
sending the rod through his eye, up through his brain,
00:27:25
taking out a big patch of his brain in the process.
00:27:30
At first people thought, well, this is a miracle.
00:27:33
This man has been unscathed from this accident.
00:27:36
He had memory, he had language, he had motor control.
00:27:41
But of course, his friends noticed a difference.
00:27:44
CHANG: His life fell apart-- he had a hard time holding a job,
00:27:46
he lost all of his friends, and he really just struggled.
00:27:52
WHEATLEY: His personality made him more fitful,
00:27:54
irreverent, more profane.
00:27:56
He was cursing a lot, lewd behavior.
00:27:58
So he had sort of no filter.
00:28:00
We now know that the parts of the brain
00:28:02
that he sort of surgically excised
00:28:05
were involved in emotion and control.
00:28:10
BERLIN: Over a hundred years later,
00:28:12
neuroscientists mapped the regions of his brain
00:28:15
that were harmed in that horrific accident.
00:28:18
Areas of his prefrontal cortex,
00:28:20
including the brain's thermostat, were damaged,
00:28:23
which might account for why he struggled socially.
00:28:26
He couldn't regulate his emotions
00:28:28
or process how other people might react to his behavior.
00:28:33
WHEATLEY: And that was the key moment, I think, in neuroscience history
00:28:37
when people realized,
00:28:39
oh, it's not just that motor, memory,
00:28:42
language is in the brain.
00:28:44
Your personality is up there, your morality is up there,
00:28:46
things that make you you are there.
00:28:50
BERLIN: I think we all kind of know intuitively that emotions
00:28:54
impact our decisions.
00:28:56
So what sort of extra information is this giving us?
00:28:59
CHANG: In a lot of the scientific work
00:29:01
that's been done on studying emotion in decision making,
00:29:03
people have really focused on
00:29:05
how emotions lead us to make worse decisions,
00:29:06
maybe even irrational.
00:29:09
And I actually don't think that's true.
00:29:11
If you have a goal to not want to harm others
00:29:13
and to do what's going to be in your self-interest,
00:29:16
emotions are actually helping us make better decisions.
00:29:19
♪ ♪
00:29:21
WHEATLEY: We are, in fact, the company that we keep,
00:29:23
because other people bring out parts of us,
00:29:27
and strengthen us in particular ways.
00:29:31
SCHILLER: How you make decisions,
00:29:32
how you behave, how you think about yourself,
00:29:35
all of these processes we develop
00:29:37
by mimicking and interacting
00:29:39
and synchronizing with other brains.
00:29:43
SAXE: One thing that we all share as humans
00:29:45
is that social life and social contact
00:29:50
is an incredibly important part of what our brain processes.
00:29:53
Our brains are, in detail, influenced
00:29:55
by every experience we have.
00:29:57
Every moment, every sentence, every image
00:29:59
changes your brain.
00:30:03
BERLIN: And certain experiences are so profound,
00:30:06
so extreme, that they can impact brain biology
00:30:09
from one generation to the next.
00:30:13
Neuroscientist Bianca Jones Marlin is studying
00:30:16
how your ancestors' experiences might control
00:30:20
how your brain is wired today.
00:30:22
MARLIN: We ask how trauma affects the brain,
00:30:25
how trauma affects the body,
00:30:27
and really, how trauma affects generations.
00:30:31
People in the world suffer from traumatic events,
00:30:34
and these traumatic events aren't just
00:30:35
a one-time change in their brain and their body.
00:30:38
It actually continues for seemingly their lifetime.
00:30:41
BERLIN: Bianca's research is inspired by her upbringing.
00:30:45
MARLIN: My parents, my biological parents,
00:30:47
were also foster parents.
00:30:49
So I had foster siblings and adopted siblings growing up.
00:30:51
Only now as a scientist, I realize that that motivates
00:30:54
a lot of the questions that I ask:
00:30:56
how do we understand what happens when kids
00:30:59
are born into trauma
00:31:01
and optimize what we do have for better generations?
00:31:03
♪ ♪
00:31:06
BERLIN: One insight comes from an event during World War II.
00:31:10
MARLIN: At the end of World War II,
00:31:12
the Netherlands were cut off from food by Nazi troops
00:31:15
because they decided to protest through the country.
00:31:17
And during this period of time, it created a man-made famine.
00:31:20
There was starvation, death, there was trauma.
00:31:23
BERLIN: Not only did those
00:31:25
who suffered during the famine experience health problems,
00:31:28
but some of their children, and even their grandchildren,
00:31:33
had metabolic issues.
00:31:36
So people began to ask, how does an experience
00:31:38
of a parent, of a grandparent, change offspring?
00:31:42
BERLIN: Researchers began to discover that your environment
00:31:47
and your experiences can change the way your genes
00:31:50
are activated in your body and in your brain.
00:31:53
MARLIN: It's not like you get your genes
00:31:56
and it's set in stone.
00:31:57
They're constantly changing based on the environment.
00:31:59
BERLIN: To see this in action,
00:32:01
Bianca studies mice.
00:32:03
MARLIN: We're able to map the whole genome of mice,
00:32:06
target certain areas
00:32:08
of that genetic code, and use them
00:32:11
to answer important questions in science.
00:32:13
BERLIN: So how could stress and trauma
00:32:16
alter the biology of the mice's offspring?
00:32:20
To find out,
00:32:22
Bianca paired the smell of almond
00:32:24
with an electric shock.
00:32:24
(shock buzzes)
00:32:26
MARLIN: Because mice really navigate the world
00:32:29
and rely heavily on the sense of smell,
00:32:31
we use olfaction, pair it with a light foot shock,
00:32:34
and we observe changes in the brain and changes in behavior.
00:32:38
BERLIN: She noticed that something inside
00:32:39
of the mice's noses changed.
00:32:44
MARLIN: We're able to look at the cells in the nose
00:32:46
that only respond to almond.
00:32:48
And what we observe is that after the light foot shock
00:32:51
and the presentation of almond coinciding,
00:32:54
there are more cells in the nose
00:32:55
that express the almond receptor.
00:32:57
It's as if something in the milieu of the nose says,
00:33:00
almond's important in this environment.
00:33:02
We need more cells like you.
00:33:04
BERLIN: Mice grew more cells
00:33:06
that responded to the smell of almond.
00:33:09
MARLIN: Each one of these green dots you see here,
00:33:12
these are neurons.
00:33:13
They're cells that can respond to the almond smell.
00:33:17
These red dots are cells that were born
00:33:20
after the presentation of odor and shock.
00:33:23
And this cell right here, this red and green cell,
00:33:27
is a cell that was born
00:33:28
after the presentation of almond and shock
00:33:30
that also responds to almond.
00:33:33
This is the cell that we want to look at
00:33:35
to see what information is inside,
00:33:37
because we see more of these
00:33:39
after the odor and shock pairing.
00:33:41
BERLIN: Remarkably, these changes were actually passed down
00:33:44
to the next generation.
00:33:48
MARLIN: The offspring, the kids of the parents
00:33:50
that were shocked with odor,
00:33:53
were born with more cells that express the almond receptor.
00:33:57
Which means there's a memory that somehow
00:33:58
is maintained in sperm and egg through implantation
00:34:02
and represented in offspring.
00:34:05
It is as if we are observing a change in evolution
00:34:09
over the time span of one generation.
00:34:14
And I just think that's fascinating.
00:34:16
Because we as humans know how
00:34:19
environment and how traumatic events change people.
00:34:24
Just being able to take the science of that
00:34:27
and being able to show that,
00:34:29
we're just justifying what we already know as humans,
00:34:32
what society has known for a long time,
00:34:33
what individuals know.
00:34:35
We just want to bring that to an undeniable truth.
00:34:41
MARTINEZ-CONDE: Our brains are not static.
00:34:43
We try to make sense of what's happening right now,
00:34:47
but we also try to make sense of what happened a long time ago
00:34:52
and to have, like, this grand picture
00:34:54
of our life as a trajectory.
00:34:58
Our ability for conscious awareness.
00:35:00
It's a magnificent ability, this ability
00:35:01
to reflect on our own minds.
00:35:03
But it also leads us astray.
00:35:06
SETH: I have memories, plans,
00:35:08
I have these feelings of agency over my actions.
00:35:12
But what the science itself is telling us is that
00:35:14
these things aren't necessarily bound together.
00:35:17
Different aspects of the self can be manipulated,
00:35:19
or even taken away altogether.
00:35:22
BERLIN: Your biology and the choices you make
00:35:25
are all molded by your social interactions
00:35:27
and even your family history.
00:35:30
And yet, we feel like we have control.
00:35:33
Like we have agency, right?
00:35:37
♪ ♪
00:35:43
MAOZ: An agent is somebody that is the author of their own story.
00:35:49
But actually,
00:35:51
most of what's happening in our brain we are not conscious of.
00:35:53
And I think this gets you starting to think,
00:35:56
wait a minute, you know,
00:35:58
is really everything under my control?
00:36:02
BERLIN: Neuroscientist Uri Maoz
00:36:03
is putting our sense of control to the test.
00:36:08
We feel like we're in control,
00:36:09
but where exactly does that
00:36:11
feeling come from, and how does it work?
00:36:14
Ah, here you are.
00:36:17
Hello.
00:36:17
Hello.
00:36:19
Thank you very much for joining us,
00:36:21
agent-ically and out of your own volition.
00:36:24
(laughs): Of course.
00:36:24
Before we start...
00:36:26
Mm-hmm.
00:36:26
...let me give you this envelope.
00:36:28
Okay.
00:36:28
Please don't let anybody touch it.
00:36:31
Okay.
00:36:31
And don't look inside, but we'll need it for later on.
00:36:34
For later, okay.
00:36:35
BERLIN: To show me how my sense of control
00:36:37
isn't always what it seems,
00:36:39
Uri kicked things off by trying to get me
00:36:41
to question my ability to choose by using a magic trick.
00:36:46
So where would you like to sit?
00:36:48
Where would I like to sit?
00:36:49
MAOZ: It's really up to you.
00:36:49
BERLIN: It's really-- I have a choice?
00:36:51
MAOZ: Wherever you want-- you have a choice.
00:36:53
All right, so I'm going to sit here.
00:36:55
You're going to sit over there, okay.
00:36:55
Yes.
00:36:56
So how about just before you sit down, if you don't mind...
00:36:58
Mm-hmm.
00:36:59
Um, let's see what this says.
00:37:03
Oh, my God, okay.
00:37:03
So...
00:37:05
So then that one obviously says the same thing, right?
00:37:09
Um...
00:37:09
No?
00:37:11
Let's check and see what this one says.
00:37:13
This one says...
00:37:13
Oh, come on.
00:37:16
Okay.
00:37:16
(laughs): So I'm that predictable?
00:37:19
You don't even know me yet!
00:37:22
BERLIN: I really don't know how he did that!
00:37:24
I'm not totally convinced, but I'm starting to question,
00:37:29
how do I know when I have made a decision?
00:37:31
If I may, let me give you,
00:37:34
as a present, a book.
00:37:35
Here you go, this is yours.
00:37:35
Oh, thank you.
00:37:37
And I will just ask you to leaf through it...
00:37:39
Mm-hmm.
00:37:39
...and find a word that has some meaning for you.
00:37:42
All right, I got it.
00:37:44
Can you tell me what the word is?
00:37:45
Representation.
00:37:47
Please write the word down, representation.
00:37:47
Mm-hmm.
00:37:49
And, you know, just stick that sticky note
00:37:51
somewhere on that page, yeah, thank you.
00:37:51
Okay, okay, all right.
00:37:53
BERLIN: We'll come back to that later.
00:37:56
But for now, I'm starting to see how choice
00:37:59
and agency aren't always so straightforward.
00:38:03
So to find out what's actually going on in the brain
00:38:06
when our sense of control is in question,
00:38:08
I took a look at a trial designed
00:38:10
by post-doctoral researcher Alice Wong.
00:38:13
A volunteer from the lab, Tomás, is being fitted
00:38:17
with a transcranial magnetic stimulation device,
00:38:21
TMS for short.
00:38:24
It generates a strong magnetic field
00:38:27
that can send signals to your brain.
00:38:29
MAOZ: The idea is that you
00:38:30
stimulate the brain using a focused magnetic field.
00:38:34
And if you stimulate that in the right part
00:38:37
of the motor cortex-- it's a part of the brain
00:38:41
that actually controls your fingers--
00:38:43
it's like you're pulling on a string here.
00:38:44
Every time you pull it, the finger goes.
00:38:48
BERLIN: With the device hooked up,
00:38:50
the researchers can make his finger jump
00:38:52
involuntarily by sending a signal to his motor cortex.
00:38:56
(device clicks)
00:38:56
WONG: We're going to be locating
00:38:59
the spot of your motor cortex that moves one of your fingers.
00:39:04
(device clicks)
00:39:05
How about that?
00:39:05
TOMÁS: That works.
00:39:06
That was a pinky movement up.
00:39:06
WONG: Okay.
00:39:10
BERLIN: Sometimes they ask him to move his finger on his own.
00:39:14
WONG: Could you replicate the movement if in, that you...
00:39:17
TOMÁS: Was something like this.
00:39:19
BERLIN: Remarkably, by recording
00:39:21
the small electrical signals that travel from his brain
00:39:24
down to his finger muscles,
00:39:26
Alice and Uri can pinpoint the exact moment
00:39:29
that Tomás's brain has initiated a movement--
00:39:32
almost 50 milliseconds before he actually moves.
00:39:36
With this information, it's as though they can predict
00:39:41
his movement slightly before it actually happens.
00:39:44
So now, his sense of agency is about to be put to the test.
00:39:49
WONG: Who initiated the movement?
00:39:50
TOMÁS: It was me.
00:39:52
WONG: How much agency did you feel over the movement?
00:39:54
TOMÁS: Quite a lot.
00:39:55
Full agency? Okay.
00:39:57
BERLIN: Normally, the researcher isn't in the room,
00:40:00
and all the questions are conducted by the computer.
00:40:04
Who initiated the movement?
00:40:08
I don't know.
00:40:11
How much agency did you feel over the movement?
00:40:15
TOMÁS: I would say some agency.
00:40:17
BERLIN: In some instances,
00:40:18
just as Tomás decides to move his finger,
00:40:23
the researchers use the magnetic field to make his finger move.
00:40:25
(device clicks)
00:40:25
WONG: Who initiated the movement?
00:40:27
I really don't know.
00:40:30
Okay.
00:40:32
How much agency did you feel over the movement?
00:40:35
A little bit.
00:40:37
BERLIN: So, even in the instances
00:40:39
when Tomás really did decide to move his finger...
00:40:42
WONG: How much agency did you feel
00:40:44
over the movement?
00:40:44
No agency at all.
00:40:47
BERLIN: ...he didn't always feel like he was in control.
00:40:50
So after the experiment, I was excited to hear the results.
00:40:54
MAOZ: When Tomás initiated the movement himself,
00:40:59
yet we intervened with the TMS,
00:41:02
Tomás said, "That wasn't me, I didn't initiate the movement.
00:41:06
It was the computer."
00:41:09
He thought that the computer initiated the movement,
00:41:11
or it was both of them, or he wasn't sure,
00:41:12
but he almost never said that it was him.
00:41:15
BERLIN: So what do you think is going on there?
00:41:17
How is this happening?
00:41:19
MAOZ: You know, we walk around and we feel like, you know,
00:41:21
we are the authors of our, of our actions and so on.
00:41:23
And you can see with just a little bit of messing around,
00:41:26
it tends to fall apart.
00:41:27
BERLIN: It's fragile, like our sense of self...
00:41:27
MAOZ: Yes.
00:41:30
BERLIN: ...our memories, our sense of agency.
00:41:32
They're all things that our brain evolved over time.
00:41:35
BERLIN: But they're fragile and they can be manipulated...
00:41:35
MAOZ: Yes.
00:41:38
BERLIN: ...under the right circumstances.
00:41:39
MAOZ: Everything has to align
00:41:41
for you to feel the sense of agency.
00:41:42
When the finger moves,
00:41:44
we get this feedback back to the brain
00:41:46
and it's incorporated with whatever is happening
00:41:48
in the brain to create the movement.
00:41:49
MAOZ: And together you get this sense of agency over the movement.
00:41:53
I think that in everyday life, we are in control.
00:41:57
However, I think this experiment shows we're quite happy
00:42:00
to relinquish control.
00:42:02
BERLIN: Like states of consciousness,
00:42:04
there are levels of agency,
00:42:05
ways it can be manipulated, and even taken away.
00:42:10
We think A happened and then B happened.
00:42:13
That's the end of the story.
00:42:15
But of course, most of our brain activity is unconscious.
00:42:18
Who initiated the first movement?
00:42:20
That was me.
00:42:23
SETH: So, we sometimes misinterpret.
00:42:24
Our experience of voluntary action
00:42:26
is a little bit retrospective in this sense.
00:42:28
The brain looks at what the body did,
00:42:30
and figures out if that makes sense
00:42:32
as an act of its own free will.
00:42:35
♪ ♪
00:42:36
BERLIN: After the agency experiment,
00:42:39
we had more important matters to attend to.
00:42:41
So, Heather, when you came in, I gave you an envelope, right?
00:42:45
Yes.
00:42:45
Nobody touched it but you?
00:42:47
No.
00:42:48
Do you remember that later on,
00:42:51
I gave you that book?
00:42:51
Mm-hmm.
00:42:53
And in that book, you opened it
00:42:54
to whatever page you wanted, and you found a word in there.
00:42:54
Mm-hmm.
00:42:58
Right, where the...
00:42:58
Can you tell us again what that word was?
00:43:00
Yes, it was on page 105.
00:43:02
And the word was "representation."
00:43:05
Representation, okay.
00:43:07
So if you don't mind just putting the book aside
00:43:10
and if you could take the envelope out now.
00:43:10
Okay.
00:43:12
Can you open it and see what's inside, please?
00:43:14
Oh, this is one of these things
00:43:16
that's gonna freak me out, right?
00:43:16
Let's see.
00:43:18
I'm getting chills.
00:43:24
Come on. No way!
00:43:27
Come on-- no, seriously!
00:43:27
(both laugh)
00:43:30
That's really freaky.
00:43:32
So you're in control, right?
00:43:34
I don't know how you did that-- that is really weird.
00:43:37
I mean, what do I do now?
00:43:38
(laughs): I don't know where to-- what do I do with that?
00:43:41
BERLIN: Uri's magic acts are tricks.
00:43:43
Sleights-of-hand and misdirection.
00:43:46
But when I saw what was written on the card,
00:43:48
I have to admit I wondered if my choices mattered at all.
00:43:52
Going to do this...
00:43:55
BERLIN: Alice Wong's experiment supports
00:43:56
the idea that it isn't just about what happens in the brain
00:43:59
at the moment a decision is made.
00:44:01
How did you do that?
00:44:03
BERLIN: Your sense of agency or control
00:44:05
also has to do with feedback you get after the decision--
00:44:09
physical, social, and emotional.
00:44:12
I think of agency as a sense, so there is a sense of agency
00:44:15
that sometimes can get disrupted, perhaps,
00:44:18
just like you have a sense of sight or smell and so on.
00:44:20
Sometimes, you have visual illusions.
00:44:22
It's similar with a sense of agency.
00:44:24
I can manipulate your sense of agency.
00:44:27
But that doesn't mean that we never
00:44:28
have a sense of agency.
00:44:30
♪ ♪
00:44:32
BERLIN: Your brain is a meaning-maker machine.
00:44:34
And creating a sense of agency
00:44:37
is one of the ways it makes meaning out of your daily life.
00:44:42
BANAJI: There is no way in which I can operate
00:44:45
without understanding
00:44:46
what is happening and why I'm doing it.
00:44:49
It's the filling-in of the blanks that is necessary
00:44:53
in some ways for survival, to give meaning, to make sense
00:44:55
of the cause and effect of things.
00:44:58
KASTHURI: Perhaps we have that feeling of consciousness
00:45:00
because it gives me a sense of agency.
00:45:03
It allows me to pretend like I'm the one making decisions
00:45:07
and I'm the one reaping the rewards
00:45:09
or the failures of that particular decision.
00:45:12
BERLIN: There are parts of the brain that allow you
00:45:15
to feel like the author of your own life.
00:45:18
But that's only part of the story.
00:45:20
(echoing): Each of our minds is actually composed
00:45:22
of lots of different pieces that are doing different things.
00:45:24
This illusion that there's a single person
00:45:27
inside our skulls.
00:45:29
MARLIN: We know how environment
00:45:31
and how traumatic events change people.
00:45:34
Our brains are, in detail, influenced
00:45:36
by the expectations of the people around us.
00:45:39
But of course, most of our brain activity is unconscious.
00:45:44
(playing slow tune)
00:45:46
BERLIN: But there are some situations where letting go
00:45:49
of conscious control can have amazing results.
00:45:55
LIMB: When you're playing the blues,
00:45:57
you have this kind of well-known musical structure,
00:45:59
this template, and then you use that
00:46:01
as a launchpad for improvisation,
00:46:02
for innovation, and for new ideas.
00:46:05
BERLIN: Charles Limb is a neuroscientist
00:46:08
trying to understand how our brain operates
00:46:11
when we are being truly creative.
00:46:13
CHRIS EMDIN: ♪ It's gon' be ill in the MRI ♪
00:46:16
BERLIN: And today,
00:46:18
he's using a scanner to peer into the brain
00:46:20
of educator and freestyle rapper Chris Emdin.
00:46:23
♪ I wonder if I'm going insane as I'm freestyling, profiling ♪
00:46:26
♪ Still wilin', it's gon' be ill ♪
00:46:28
You ready for me?
00:46:28
WOMAN: Yes.
00:46:33
LIMB: Okay, remember, keep your head still
00:46:35
during the entire thing and try not to move your feet
00:46:38
or your hands at all during the rapping.
00:46:40
EMDIN (on speaker): Okay, doing the best I can.
00:46:41
Yeah, awesome, thank you.
00:46:43
BERLIN: First, Charles asks Chris to perform a memorized piece.
00:46:48
Now, that memory means you're going to do the memorized lyrics
00:46:50
the way you originally wrote them.
00:46:52
Okay?
00:46:52
EMDIN: Okay.
00:46:55
LIMB: Memory.
00:46:56
EMDIN: ♪ I'm a physicist, lyricist, spitting this ridiculousness ♪
00:46:59
♪ So witness the ignorance I dismiss ♪
00:46:59
Up a little bit?
00:47:01
♪ Feelings and emotion is the topic of the course ♪
00:47:03
♪ Staying motionless to handle balanced force ♪
00:47:06
BERLIN: Next, he gives him a prompt and asks him
00:47:09
to improvise-- to create a new, original piece on the spot.
00:47:14
He doesn't know what's coming.
00:47:14
Mm-hmm.
00:47:16
And that's going to be his cues for that.
00:47:18
LIMB: Freestyle: physicist.
00:47:20
EMDIN: ♪ Physicist, lyricist ♪
00:47:23
♪ Emcees like this will always be kicking this ♪
00:47:25
♪ After all of that it'll all be over ♪
00:47:26
♪ Lucky like I picked a four-leaf clover ♪
00:47:30
♪ Can't move my shoulder ♪
00:47:32
♪ 'Cause the MRI machine won't let me do it ♪
00:47:34
♪ But you wouldn't know what it is that it's like ♪
00:47:34
(laughs)
00:47:36
♪ I'm like a baseball player the way I strike ♪
00:47:39
♪ With the raps... ♪
00:47:39
LIMB: Stop.
00:47:41
(chuckles): He's good.
00:47:44
BERLIN: So, what does improvisation or spontaneous creativity
00:47:47
look like in the brain?
00:47:50
LIMB: What we found was that
00:47:51
the prefrontal cortex that appears to be linked
00:47:55
to effortful self-monitoring
00:47:58
seemed to be turning off,
00:48:00
deactivating, in a pretty intense way
00:48:03
in these highly trained professional musicians
00:48:05
when they start improvising.
00:48:07
So in some sense, by letting go, by decreasing activation
00:48:12
in the prefrontal cortex,
00:48:14
we can sort of gain control of our lives in a way.
00:48:17
LIMB: In fact, if you're too self-conscious
00:48:19
and you're unable to relax and let go,
00:48:21
you can't do something like this.
00:48:23
When you start trying to put conscious control mechanism,
00:48:26
your performance goes down-- you get worse.
00:48:27
So would you say this goes to, to any activity,
00:48:29
really, if you're, for a professional tennis player
00:48:32
or if you're trying to do a physical activity,
00:48:34
that the more you're able to practice letting go,
00:48:37
once you've learnt the skill, the better you'll be.
00:48:37
Exactly.
00:48:40
LIMB: Free throw shooters that are able to shoot 99% free throws,
00:48:44
all of a sudden, when you tell them
00:48:46
you're going to get a million dollars
00:48:48
if you make the next one...
00:48:48
Mm-hmm.
00:48:49
Then all of a sudden, you inject conscious control over something
00:48:52
that's much better just to left to its own subconsciousness.
00:48:54
And then your performance gets worse,
00:48:56
and you're more likely to choke.
00:48:57
BERLIN: Surprisingly, the parts of your brain
00:49:00
that are usually in control can get in your way.
00:49:04
Your prefrontal cortex, the decision maker,
00:49:07
can make you overthink something you've done a thousand times.
00:49:13
LIMB: Freestyle: stay.
00:49:15
EMDIN: ♪ Yes, you want me to stay ♪
00:49:17
♪ Relaxed, but I won't never play ♪
00:49:19
LIMB: Every human being is creative.
00:49:23
Whether they're creative artistically or not
00:49:24
is another question, but we're all creative.
00:49:27
We have to be, because all day long, we're doing
00:49:29
unscripted things that we didn't know we would be doing.
00:49:31
Life is not scripted.
00:49:34
And so no matter who you are
00:49:35
in this world, you're doing things that are unplanned.
00:49:40
BERLIN: All day long, we're balancing forces
00:49:42
that push us around, even if we're not aware of them,
00:49:45
from past trauma to the emotions of others,
00:49:49
and all the hidden forces affecting your brain.
00:49:52
KASTHURI: I'd like to believe that I am in charge of my life,
00:49:55
that I am the agent of my life,
00:49:58
that I actually can control my emotions,
00:50:01
my abilities, my desires.
00:50:03
And the more I learn about brains, the more I realize
00:50:05
that this is probably not true.
00:50:08
SETH: We can be influenced by our social networks,
00:50:10
by our culture, by our genetics,
00:50:13
by our development, by our childhood.
00:50:17
(clock ticking)
00:50:19
BERLIN: Your brain is a complicated collection
00:50:21
of these intricate parts,
00:50:24
many of which you have no awareness of,
00:50:26
and they all work together in a delicate dance
00:50:29
to create your perception of you.
00:50:33
KANWISHER: The brain is who you are.
00:50:36
It's really different than any other organ in that sense.
00:50:39
MARTINEZ-CONDE: We know that every experience,
00:50:41
every thought, every memory,
00:50:44
every sensation has its origin in the brain.
00:50:49
KASTHURI: The brain is made of almost 90 billion neurons,
00:50:52
but it produces the idea
00:50:53
that there's a single thing inside my head.
00:50:56
My particular pattern of neuronal connections,
00:50:58
it actually creates me.
00:51:00
And your particular pattern of neuronal connections
00:51:02
actually creates you.
00:51:06
BERLIN: Years of studying the brain have humbled me.
00:51:09
BERLIN: He looks scared.
00:51:11
BERLIN: You can't control everything
00:51:13
that makes you who you are.
00:51:16
But the unconscious you is still you.
00:51:20
BANAJI: The vast majority
00:51:23
of the brain's work is happening outside conscious awareness.
00:51:27
(crowd groans)
00:51:27
LIMB: If you try to over-control some things,
00:51:29
you actually will decrease your performance.
00:51:31
LIMB: You have to let go
00:51:34
of conscious self-monitoring to just kind of, like,
00:51:36
go with the flow.
00:51:38
It could be scary to say and scary to hear,
00:51:40
but we are not just our own.
00:51:43
WHEATLEY: We are all multifaceted, multi-dimensional people.
00:51:47
BERLIN: And by becoming more aware
00:51:49
of the unconscious processes in your own brain,
00:51:53
you can become more aware of what drives you,
00:51:55
and what you ultimately can control.
00:52:13
♪ ♪
00:52:25
♪ ♪
00:52:34
♪ ♪
00:52:43
♪ ♪
00:52:56
♪ ♪

الوسوم

brain
consciousness
unconscious
agency
sleepwalking
anesthesia
split-brain
emotion
trauma
neuroscience