Huberman Lab - Understand and Use Dreams to Learn and Forget
Episode Date: February 1, 2021This episode is all about the two major kinds of dreams and the sorts of learning and unlearning they are used for. I discuss REM-associated dreams that control emotional learning and their similarity... to various trauma treatments such as ketamine and EMDR. I also discuss Non-REM dreams and their role in motor learning and learning of detailed, non-emotionally-laden information. I relate this to science-backed tools for accessing more of the types of sleep and learning people may want. Other topics are listed in the time stamps below. Read the full show notes for this episode at hubermanlab.com. Thank you to our sponsors AG1: https://athleticgreens.com/huberman LMNT: https://drinklmnt.com/hubermanlab Waking Up: https://www.wakingup.com/huberman Timestamps 00:00:00 Introduction 00:00:30 Sponsors: AG1, LMNT & Waking Up 00:03:00 The Dream Mask 00:06:00 Cycling Sleep 00:08:10 Chemical Cocktails of Sleep 00:13:00 Motor Learning 00:16:30 High Performance with Less Sleep 00:17:45 Rapid Eye Movement Sleep 00:20:30 Paralysis & Hallucinations 00:23:35 Nightmares 00:24:45 When REM & Waking Collide 00:25:00 Sleeping While Awake 00:26:45 Alien Abductions 00:29:00 Irritability 00:30:00 Sleep to Delete 00:32:25 Creating Meaning 00:34:10 Adults Acting Like Children 00:36:20 Trauma & REM 00:37:15 EMDR 00:39:10 Demo 00:44:25 Ketamine / PCP 00:45:45 Soup, Explosions, & NMDA 00:48:55 Self Therapy 00:50:30 Note About Hormones 00:51:40 Measuring REM / SWS 00:53:15 Sleep Consistency 00:56:00 Bed Wetting 00:58:00 Serotonin 00:59:00 Increasing SWS 00:59:50 Lucidity 01:02:15 Booze / Weed 01:03:50 Scripting Dreams 01:04:35 Theory of Mind 01:07:55 Synthesis 01:10:00 Intermittent Sleep Deprivation 01:11:10 Snoring Disclaimer 01:11:40 New Topic 01:15:50 Corrections 01:17:25 Closing Remarks Disclaimer & Disclosures Learn more about your ad choices. Visit megaphone.fm/adchoices
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Welcome to the Huberman Lab podcast, where we discuss science and science-based tools for everyday life.
I'm Andrew Huberman and I'm a professor of neurobiology and ophthalmology at Stanford School of Medicine.
This podcast is separate from my teaching and research roles at Stanford.
It is, however, part of my desire to bring you zero cost to consumer information about science and science-related tools.
In keeping with that theme, I'd like to thank the sponsors of today's podcast.
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Today we're going to talk about dreaming,
learning during dreaming,
and unlearning during dreaming,
in particular, unlearning of troubling emotional events.
Now my interest in dreaming goes way back.
When I was a child, I had a friend,
and he came over one day and he brought with him a mask
that had a little red light in the corner.
He had purchased this thing through some magazine ad
that he had seen.
And this mask was supposed to trigger lucid dreaming.
Lucid dreaming is the experience of dreaming during sleep,
but being aware that one is dreaming.
And in some cases, being able to direct one
dream activities.
So if you're in a lucid dream
and you want to fly for instance,
some people report being able to initiate
that experience of flying
or to contort themselves into an animal
or to transport themselves
to wherever they want within the dream.
I tried this device.
The way it worked is you put on the mask
during a waking state wide awake
and you'd look at the little light flashing in the corner
and then you'd also wear it when you went to sleep at night.
And indeed, while I was,
I could see the red light, presumably through my eyelids, although for all I know, I had opened my eyes. I
don't know. I was asleep. And then because I was dreaming and I was experiencing something very vivid,
I was able to recognize that I was dreaming and then start to direct some of the events within that dream.
Now, lucid dreaming occurs in about 20% of people. And in a small percentage of those people,
they lucid dream almost every night. So much so that many of them report their sleep not being as restorative as it would be
otherwise. Now, all of this is to say that lucid dreaming and dreaming are profound experiences.
We tend to feel extremely attached to our dream experience. This may explain the phenomenon of
people who have a very intense dream. They need to somehow tell everybody about that dream or tell
someone about that dream. I don't really know what that behavior is about, but sometimes we wake up
and we feel so attached to what happened in this state that we call dreaming that there seems to be an
intense need to share it with other people,
presumably to process it and make sense of it.
Now, numerous people throughout history
have tried to make sense of dreams
and in some sort of organized way,
the most famous of which of course is Sigmund Freud,
who talked about symbolic representations in dreams.
A lot of that has been kind of debunked,
although I think that there's some interest
in what the symbols of dreaming are.
And this is something that we'll talk about
in more depth today,
although not Freudian theory in particular.
So I think in order to really think about dreams
and what to do with them and how to maximize the dream experience
for sake of learning and unlearning,
the best way to address this is to look at the physiology of sleep,
to really address what do we know concretely about sleep?
So first of all, as we get sleepy,
we tend to shut our eyes and that's because there are
some autonomic centers in the brain,
some neurons that control closing of the eyelids
when we get sleepy.
And then we transition into sleep.
And sleep, regardless of how long we sleep,
is generally broken up into a series of 90 minute cycles,
these ultradian cycles.
So early in the night, these 90 minute cycles
tend to be comprised more of shallow sleep
and slow wave sleep.
So stage one, stage two, et cetera,
and what we call slow wave sleep.
I'll go into detail about what all this means in a moment.
And we tend to have less so called REM sleep,
R-E-M sleep, which stands for rapid eye movements,
sleep and I'll talk about rapid eye movement sleep in detail.
So early in the night, a lot more slow wave sleep
and less REM.
For every 90 minute cycle that we have during a night of sleep,
we tend to start having more and more REM sleep.
So more of that 90 minute cycle is comprised of REM sleep
and less of slow wave sleep.
Now this is true regardless of whether or not
you wake up at the middle of the night to use the restroom
or your sleep is broken.
The more sleep you're getting,
across the night, the more REM sleep you're going to have.
And REM sleep and non-REM, as I'll refer to it,
have distinctly different roles in learning and unlearning,
and they are responsible for learning and unlearning
of distinctly different types of information.
And this has enormous implications
for learning of motor skills,
for unlearning of traumatic events,
or for processing emotionally challenging,
as well as emotionally pleasing events.
And as we'll see,
one can actually leverage their daytime activities
in order to access more slow wave sleep
or non-REM sleep, as we'll call it,
or more REM sleep depending on your particular emotional
and physical needs.
So it's really a remarkable stage of life
that we have a lot more control and power over
than you might believe.
We'll also talk about lucid dreaming.
We're also going to talk about hallucinations
and how drug-induced hallucinations
have a surprising similarity
to a lot of dream states
and yet some really important differences.
Okay, so let's start by talking about slow wave sleep or non-REM sleep.
Now, I realize that slow-wave sleep and non-REM sleep aren't exactly the same thing.
So for you sleep officiados out there, I am lumping right now.
As we say in science, there are lumpers and there are splitters.
And I am both.
Sometimes I lump, sometimes I split.
For sake of clarity and ease of conversation right now, I'm going to be a lumper.
So when I say slow-wave sleep, I mean non-REM sleep.
generally, although I acknowledge there is a distinction. Slow wave sleep. So slow wave sleep is characterized
by a particular pattern of brain activity in which the brain is metabolically active, but that there's
these big sweeping waves of activity that include a lot of the brain. If you want to look this up,
there you can find evidence for sweeping of waves of neural activity across association cortex, across big swaths of
of the brain stem, the so-called pawns,
geniculate occipital pathway.
This is brain stem, thalamus, and then cortex,
for those of you that are interested,
although more of that is going to occur in REM sleep.
Now the interesting thing about slow wave sleep
are the neuromodulators that tend to be associated with it
that are most active and least active during slow wave sleep.
And here's why.
To remind you, neuromodulators are these chemicals,
that act rather slowly,
but their main role is to bias particular brain circuits
to be active and other brain circuits to not be active.
These are like the music playlist.
So think of neuromodulators,
and these come in the names of acetylcholine,
noraphen, serotonin, and dopamine.
Think of them as suggesting playlists on your audio device.
So, you know, classical music is distinctly different
in feel and tone
and a number of other features from like,
third wave punk or from, you know, hip hop, right?
So think of them as biasing toward particular genres
of neural circuit activity, okay?
Mellow music versus really aggressive fast music
or rhythmic music that includes lyrics
versus rhythmic music that doesn't include lyrics.
That's more or less the way to think about these neuromodulators.
And they are associated as a consequence
with certain brain functions.
So we know for instance, and just to review
acetycholine in waking,
is a neuromodulator that tends to amplify
the activity of brain circuits associated
with focus and attention.
Noropenephrine is a neuromodulator
that tends to amplify the brain circuits associated
with alertness and the desire to move.
Serotonin is the neuromodulator that's released
and tends to amplify the circuits
in the brain and body that are associated with bliss
and the desire to remain still.
And dopamine is the neuromodulator
that's released and is associated with amplification
of the neural circuits in the brain and body associated
with pursuing goals and pleasure and reward.
Okay.
So in slow wave sleep, something really interesting happens.
There's essentially no acetylcholine.
Acetylcholine production and release and action
from the two major sites, which are in the brain stem,
which from a nucleus, if it's a paribigeminal nucleus,
if you really wanna know, or from the forebrain,
which is nucleus basalis, and you don't need to know these names,
but if you like, that's why I put them out there.
Acetylcholine production plummets.
It's just almost to zero.
And acetycholine, as I just mentioned,
is associated with focus.
So you can think of slow wave sleep
as these big sweeping waves of activity through the brain
and a kind of distortion of space and time
so that we're not really focusing on any one thing.
Now, the other molecules that are very active at that time
are norepinephrine,
which is a little bit surprising
because normally in waking,
states, noropenephrine is going to be associated
with a lot of alertness and the desire to move.
But there's not a ton of norapinephrine around in slow wave sleep,
but it is around.
So there's something associated with the movement circuitry
going on in slow wave sleep.
And remember, this is happening mostly at the beginning of the night.
Your sleep is dominated by slow wave sleep.
So no acetylcholine, very little norephene,
although there is some, and a lot of serotonin.
And serotonin again is associated with this desire,
the sensation of,
kind of bliss or well-being, but not a lot of movement.
And during sleep, you tend not to move.
Now, in slow-wave sleep, you can move.
You're not paralyzed, so you can roll over.
If people are going to sleepwalk, typically,
it's going to be during slow-wave sleep.
And what studies have shown through some kind of sadistic experiments
where people are deprived specifically of slow-wave sleep,
and that can be done by waking them up
as soon as the electrode recording show
that they're in slow-wave sleep,
or by chemically altering their sleep
so that it biases them away from slow wave sleep.
What studies have shown is that motor learning
is generally occurring in slow wave sleep.
So let's say the day before you go to sleep,
you were learning some new dance move
or you were learning some specific motor skill,
either a fine motor skill or a course motor skill.
So let's say it's a new form of exercise
or some new coordinated movements.
This could be,
coordinate movement at the level of the fingers,
or it could be coordinated movement
at the level of the whole body and large limb movements.
It could involve other people
or it could be a solo activity.
Learning of those skills
is happening primarily during slow wave sleep
in the early part of the night.
In addition, slow wave sleep has been shown
to be important for the learning of detailed information.
Now this isn't always cognitive information.
We're gonna talk about cognitive information,
but the studies that have been done along these lines
involve having people learn very detailed information
about very specific rules and the way
that certain words are spelled,
they tend to be challenging words.
So if people are tested in terms of their performance
on these types of exams
and they're deprived of slow wave sleep,
they tend to perform very poorly.
So we can think of slow wave sleep
as important for motor learning,
motor skill learning,
and for the learning of specific details
about specific events.
And this turns out to be fundamentally important
because now we know that slow wave sleep
is primarily in the early part of the night
and motor learning is occurring primarily early in the night
and detail learning is occurring early in the night.
Now for those of you that are waking up
after only three, four hours of sleep,
this might be informative.
This might tell you a little something
about what you are able to learn
and not able to learn if that were to be the only sleep that you get.
Although hopefully that's not the only sleep that you get.
but we're going to dive deep into how it is
that one can maximize motor learning
in order to extract say more detail information
about coordinated movements and how to make them faster
or slower. So that might be important for certain sports.
It might be almost certainly important for certain sports.
It's going to be important for any kind of coordinated movement
like say learning to play the piano or for instance how to
learn synchronized movements with somebody else.
So maybe I mentioned the example of dance earlier.
If you, like me a few years ago,
I set out to learn tango because I have some Argentine relatives
and I was abysmal.
I need to return to that at some point.
I was just abysmal.
And one of the worst things about being abysmal
at learning dance is that somebody else has
to suffer the consequences also.
So I don't know, maybe in the month on neuroplasticity,
I'll explore that again as a,
the self-expermentation.
But the key things to know are slow-wave sleep
involved in motor learning and detailed learning.
There's no acetylcholine around at that time,
has these big amplitude activity sweeping throughout the brain
and that there's the release of these neuromodularis,
norephenephrine and serotonin.
And again, that's all happening early in the night.
So athletes, people that are concerned about performance,
if you happen to wake up after just a couple hours
of three, four hours,
of sleep because you're excited about a competition the next day.
Presumably, if you've already trained the skills that you need for the event,
you should be fine to engage in that particular activity.
Now, it's always going to be better to get a full night sleep.
And a full night sleep for you is six hours.
And it's always going to be better to get more sleep than it is to get less.
However, I think some people get a little bit overly concerned that if they didn't get their full night sleep,
before some sort of physical event,
that their performance is going to plummet.
Presumably, if you've already learned what you need to do
and it's stored in your neural circuits
and you know how to make those coordinated movements,
what the literature on slow wave sleep suggests
is that you would be replenished,
that the motor learning and the recovery from exercise
is going to happen early in the night.
So we'll just pause there and kind of shelve that for a moment
and then we're gonna come back to it.
But I wanna talk about REM sleep or rapid eye movement sleep.
Rem sleep and rapid eye movement,
sleep, as I mentioned before, occurs throughout the night,
but you're gonna have more of it.
A larger percentage of these 90 minute sleep cycles
is going to be comprised of REM sleep as you get toward morning.
Rem sleep is fascinating.
It was discovered in the 50s when sleep laboratory in Chicago,
the researchers observed that people's eyes
were moving under their eyelids.
Now, something very important that we're going to address
when we talk about trauma later is that the eye movements
are not just side to side.
They're very erratic in all different directions.
One thing that I don't think anyone,
I've never heard anyone really talk about publicly
is why eye movements during sleep.
Eyes are closed and sometimes people's eyelids
will be a little bit open and their eyes are darting around
especially in little kids.
I don't suggest you do this.
I'm not even sure it's ethical,
but it has been done where you pull back the eyelids
of a kid while they're sleeping
and their eyes are kind of darting all over the place.
I think people do this to their passed out friends
at parties and things like that.
So again, I don't suggest you do it,
but I'll tell you it because it's been done before
and therefore you don't have to do it again.
But rapid eye movement sleep is fascinating
and occurs because there are connections
between the brain stem, an area called the pawns,
and areas of the thalamus
and the top of the brainstem
that are involved in generating movements
in different directions, sometimes called saccades,
although sometimes during rapid eye movement sleep,
it's not just rapid, it's kind of a jittery side to side thing
and then the eyeballs kind of roll
It's really pretty creepy to look at if you see.
So what's happening there is the circuitry
that's involved in conscious eye movements
is kind of going haywire, but it's not haywire.
It's these waves of activity from the brain stem
up to the so-called thalamus,
which is an area that filter sensory information
and then up to the cortex.
And the cortex of course is involved
in conscious perceptions.
So in rapid eye movement sleep,
there are a couple things are happening
besides rapid eye movements.
The main ones are that they're in contrast
to slow wave sleep, in REM sleep,
serotonin is essentially absent.
So this molecule, this neuromodulator
that tends to create the feeling of bliss and well-being
and just calm, placidity is absent.
All right, so that's interesting.
In addition to that,
nor epinephrine, this molecule that's involved
in movement and alertness is absolutely,
absolutely absent.
It's probably one of the few times in our life
that epinephrine is essentially at zero activity
within our system.
And that has a number of very important implications
for the sorts of dreaming that occur during REM sleep
and the sorts of learning that can occur in REM sleep and unlearning.
First of all, in REM sleep, we are paralyzed.
We are experiencing what's called atonia,
which just means that we're completely laid out
and paralyzed.
We also tend to experience whatever it is
that we're dreaming about as a kind of hallucination
or a hallucinatory activity.
Long ago, I looked into hallucinations and dreaming.
I was just fascinated by this in high school.
And there's some great books on this
if you're interested in exploring the relationship
between hallucinations and dreaming,
the most famous of which are from a guy,
researcher at Harvard, Alan Hobson,
a book called Dream Drugstore
and talked all about the similarities
between drugs that induce hallucinations
and dreaming in REM.
So you can explore that if you like.
So in REM, our eyes are moving,
but the rest of our body is paralyzed
and we are hallucinating.
There's no epinephrine around.
Epinephrine doesn't just create a desire to move and alertness.
It is also the chemical signature
of fear and anxiety.
It's what's really,
released from our adrenal glands
when we experience something that's fearful or alerting.
So if a car suddenly screeches in front of us
or we get a troubling text message,
adrenaline is deployed into our system.
Adrenaline is epinephrine.
Those are equivalent molecules.
And epinephrine isn't just released from our adrenals,
it's also released within our brain.
So there's this weird stage of our life
that happens more toward morning
that we call REM sleep,
where we're hallucinating and having
these outrageous experiences in our mind,
but the chemical that's associated with fear and panic
and anxiety is not available to us.
And that turns out to be very important.
And you can imagine why that's important.
It's important because it allows us to experience things,
both replay of things that did occur,
as well as elaborate contortions of things
that didn't occur, and it allows us to experience
those in the absence of fear and anxiety.
And that, it turns out, is very important for adjusting our emotional relationship to
challenging things that happened to us while we were awake.
Those challenging things can sometimes be in the form of social anxiety or just having
been working very hard or concern about an upcoming event or sometimes people report,
for instance, dreams where they find themselves late to an exam or, or, you know,
naked in public or in some sort of situation
that would be very troubling to them.
And that almost certainly occurs during REM sleep.
So we have this incredible period of sleep
in which our experience of emotionally laid in events
is dissociated, it's chemically blocked
from us having the actual emotion.
Probably immediately some of you are thinking,
well, what about nightmares?
I have nightmarers.
have nightmares and those carry a lot of emotion
or sometimes I'll wake up in a panic.
Let's consider each of those two things separately
because they are important in understanding REM sleep.
There's a good chance that nightmares
are occurring during slow wave sleep.
There are actually some drugs that I don't suggest people take.
In fact, so much so I'm not gonna mention them
that give people very kind of scary or eerie dreams
and this kind of feeling that things are pursuing them
that they can't move when they are being chased.
That's actually a common dream that I've had.
I guess it's more or less a nightmare.
The feeling that one is paralyzed and can't move
and is being chased.
A lot of people have said,
oh, that must be in REM sleep because you're paralyzed
and so you're dreaming about being paralyzed
and you can't move.
I think that's probably false.
The research says that because nor epinephrine
is absent during REM sleep,
it's very unlikely that you can have these intense, fearful memories.
So those are probably occurring in slow wave sleep.
although there might be instances
where people have nightmares in REM sleep.
The other thing is some people experience,
certainly I've had this experience of waking up
and feeling very stressed about whatever it was
that I happen to be thinking about
or dreaming about in the moments before.
And that's an interesting case of an invasion
of the dream state into the waking state
and the moment you wake up, epinephrine is available.
So the research on this isn't fully chrystic
fully crystallized, but most of it points in the direction of the experience of waking up and
feeling very panicked. Maybe, I want to highlight May, but maybe that you were experiencing
something that was troubling in the daytime, you're repeating that experience in your sleep.
Epinephrine is not available and therefore the brain circuits associated with fear and anxiety
are shut off and so you're able to process those events. And then suddenly you wake up
and there's a surge of adrenaline of epinephrine
that's now coupled to that experience.
So nightmare is very likely in slow wave sleep
and that kind of panic on waking from something
very likely to be an invasion of the thoughts and ideas,
however distorted in REM sleep, invading the waking state.
In fact, that brings to mind something
that I've mentioned once before,
but I wanna mention again, this atonia,
this paralysis that we experienced during sleep,
can invade the waking state.
Many people report the experience of waking up
and being paralyzed.
They're legitimately waking up, it's not a dream,
waking up and being paralyzed and it is terrifying.
I've had this happen before it is,
I can tell you, terrifying to be wide awake.
And as far as I could tell, fully conscious,
but unable to move.
And then generally you can jolt yourself out of it
in a few seconds, but it is quite frightening.
Now some people actually experience waking
up being fully paralyzed and hallucinating.
And there is a theory in the academic
and scientific community at least
that what people report as alien abductions
have a certain number of core characteristics
that map quite closely,
eerily similarly to these experiences.
A lot of reports of alien deduction involve people
being unable to move, seeing particular faces,
hallucinating extensively feeling like their body
is floating or they were transported.
This is very similar to the experience
of invasion of Aetonia into the waking state,
waking up and still being paralyzed,
as well as the hallucinations that are characteristic
of dreaming in REM sleep.
Now, I'm not saying that people's alien abductions
were not legitimate alien abductions.
How could I?
I wasn't there.
And if I was there, I wouldn't tell you
because that would make me an alien
and I wouldn't want you to know.
But it is,
quite possible that people are experiencing these things
and they are an invasion of the sleep state
into the waking state and they can last several minutes or longer.
And because in dreams space and time are distorted,
our perception of these events could be that they lasted many hours
and we can really feel as if they lasted many hours
when in fact they took only moments.
And we're gonna return to distortion of space and time
in a little bit.
So to just recap where we've gone so far,
slow wave sleep early in the night,
It's been shown to be important for motor learning
and for detail learning.
Rem sleep has a certain dream component
in which there's no epinephrine,
therefore we can't experience anxiety, we are paralyzed.
Those dreams tend to be really vivid
and have a lot of detail to them.
And yet in REM sleep, what's very clear
is that the sorts of learning that happen in REM sleep
are not motor events, it's more about unlearning
of emotional events.
And now we know why,
because the chemicals available for really feeling those emotions
are not present.
Now that has very important implications.
So let's address those implications from two sides.
First of all, we should ask what happens
if we don't get enough REM sleep?
And a scenario that happens a lot
where people don't get enough REM sleep is the following.
I'll just explain the one that I'm familiar with
because it happens to me a lot,
although I figured out ways to adjust.
I go to sleep around 10, 30, 11 o'clock.
I fall asleep very easily, and then I wake up around 3 or 4 a.m.
I now know to use a NSDR, a non-sleep deep rest protocol,
and that allows me to fall back asleep,
even though it's called non-sleep deep rest.
It's really allows me to relax my body and brain
and I tend to fall back asleep and sleep
till about 7 a.m.
During which time I get a lot of REM sleep.
And I know this because I've measured it
and I know this because my dreams
tend to be very intense of the sort
that we know as typical of REM sleep.
In this scenario, I've gotten my slow wave sleep early in the night
and I've got my REM sleep toward morning.
However, there are times when I don't go back to sleep.
Maybe I have a flight to catch that's happened.
Sometimes I've got a lot of my mind
and I don't go back to sleep.
I can tell you and you've probably experienced
that the lack of REM sleep tends to make people emotionally irritable.
It tends to make us,
feel as if the little things are the big things.
So it's very clear from laboratory studies
where people have been deprived selectively of REM sleep
that our emotionality tends to get a little bit unhinged
and we tend to catastrophize small things.
We tend to feel like the world is really daunting.
We're never going to move forward in the ways that we want.
We can't unlearn the emotional components
of whatever it has been happening,
even if it's not traumatic.
The other thing that happens in
REM sleep is a replay of certain types of spatial information
about where we were and why we were in those places.
And this maps to some beautiful data and studies
that were initiated by a guy named Matt Wilson at MIT
years ago showing that in rodents,
and it turns out in other non-human primates and in humans,
there's a replay of spatial information during REM sleep
that almost precisely maps to the activity
that we experienced during the day
as we move from one place to another.
So here's a,
common world scenario, you go to a new place,
you navigate through that city or that environment.
This place doesn't have to be at the scale of a city.
It can be a new building,
it could be finding particular rooms,
new social interaction.
You experience that and if it's important enough,
that becomes solidified a few days later
and you won't forget it.
If it's unimportant, you'll probably forget it.
During REM sleep, there's a literal replay
of the exact firing of the neurons that occurred
while you were navigating that same city
your building earlier.
So REM sleep seems to be involved
in the generation of this detailed spatial information.
But what is it that's actually happening in REM sleep?
So there's this uncoupling of emotion,
but most of all what's happening in REM sleep
is that we're forming a relationship
with particular rules or algorithms.
We're starting to figure out,
based on all the experience that we had during the day,
whether or not it's important that we avoid
certain people or that we approach certain people.
Whether or not it's important that, you know,
when we enter a building that we go into the elevator
and turn left where the bathroom is, for instance,
these general themes of things and locations
and how they fit together.
And that has a word.
It's called meaning.
During our day, we're experiencing all sorts of things.
Meaning is how we each individually piece together
the relevance of one thing to the next, right?
So if I suddenly,
that told you that this pen was downloading
all the information to my brain
that was important to deliver this information,
you'd probably think I was a pretty strange character
because typically we don't think of pens
as downloading information into brains.
But if I told you that I was getting information
from my computer that was allowing me to say things to you,
you'd say, well, that's perfectly reasonable.
And that's because we have a clear and agreed upon association
with computers and information and memory,
and we don't have that same association with pens.
You might say well, duh, but something in our brain
needs to solidify those relationships
and make sure that certain relationships don't exist.
And it appears that REM sleep is important for that
because when you deprive yourself or people of REM,
they start seeing odd associations.
They tend to lump or batch things.
I know this from my own experience,
if I've ever been sleep deprived,
which unfortunately happens too often
because of I'm terrible with deadlines,
pull in all nighter, the word the the
starts to look like it's spelled incorrectly.
And the is a very simple word to spell,
but things start to look a little distorted.
And we know that if people are deprived of REM sleep
for very long periods of time, they start hallucinating.
They literally start seeing relationships
and movement of objects that isn't happening.
And so REM sleep is really where we establish
the emotional load, but where we also start
discarding of all the meanings that are irrelevant,
And if you think about emotionality,
a lot of over-emotionality or catastrophizing
is about seeing problems everywhere.
And you could imagine why that might occur
if you start linking the web of your experience too extensively.
It's very important in order to have healthy emotional
and cognitive functioning that we have fairly narrow channels
between individual things.
If we see something on the news that's very troubling,
well then it makes sense to be very troubled.
But if we're troubled by everything
and we start just saying, you know,
everything is bothering me
and I'm feeling highly irritable
and everything is just distorting and troubling me.
Chances are we are not actively removing the meaning,
the connectivity between life experiences as well as we could.
And that almost always maps back to a deficit in REM sleep.
So REM sleep is powerful and has this amazing capacity
to eliminate the meanings that don't matter.
It's not that it exacerbates,
the meanings that do matter,
but it eliminates the meanings that don't matter.
And that bears a striking resemblance
to what happens early in development.
This isn't a discussion about early in development,
but early in development, the reason a baby
can't generate coordinated movements
and the reason why children can get very emotional
about what seems like trivial events
or what adults know to be trivial events,
like, oh, the ice cream shop is closed
and then the kid just dissolves into a puddle of tears.
And the parents can, okay, well, it'll be open again another time.
The children, one of the reasons that they can't generate coordinated movement
or place that event of the ice cream shop being closed into a larger context
is because they have too much connectivity.
And much of the maturation of the brain and nervous system
that brings us to the point of being emotionally stable,
reasonable, rational human beings is about elimination
of connections between things.
So REM sleep seems to be where we uncouple
the potential for emotionality between various experiences.
And that brings us to the absolutely fundamental relationship
and similarity of REM sleep to some of the clinical practices
that have been designed to eliminate emotionality
and help people move through trauma
and other troubling experiences.
Whether or not those troubling experiences
are a death in the family or of a close loved one,
something terrible that happened to you or somebody else,
or an entire childhood or some event
that in your mind and body is felt as
and experienced as bad, terrible or concerning.
Many of you perhaps have heard of trauma treatment
such as EMDR, I movement desensitization reprocessing
or ketamine treatment for trauma,
something that recently became legal
and is in fairly widespread clinical use.
Interestingly,
Interestingly enough, EMDR and ketamine
at kind of a core level,
bear very similar features to REM sleep.
So let's talk about EMDR first.
EMDR, eye movement desensitization reprocessing,
something that was developed by a psychologist,
Francine Shapiro.
She actually was in Palo Alto.
And the story goes that she was walking,
not so incidentally,
the trees and forest behind Stanford.
And she was recalling a troubling event in her own mind.
So this would be from her own life.
And she realized that as she was walking,
the emotional load of that experience
was not as intense or severe.
She extrapolated from that experience
of walking and not feeling as stressed
about the stressful event to a practice
that she put into work with her clients,
with her patients,
and that now has become fairly widespread.
It's actually one of the few behaviorally,
the behavior treatments that are approved
by the American Psychological Association
for the treatment of trauma.
What she had her clients and patients do
was move their eyes from side to side
while recounting some traumatic or troubling event.
Now this was of course in the clinic
and I'm guessing that she removed the walking component
and just took the eye movement component
to the clinic because while it,
would be nice to go on therapy sessions
with your therapist and take walks.
It has, there are certain boundaries to that,
such as confidentiality, you know,
if there are a lot of people around,
the person might not feel as open to discussing things
or weather barriers and things like,
you know, if it's raining or hailing outside,
it gets tough to do.
Why eye movements?
Well, she never really said why eye movements,
but soon I'll tell you why the decision
to select these lateralized eye movements
for the work in the clinic,
was the right one.
So these eye movements, they look silly.
I'll do them because that's why I'm here.
They look silly, but they basically involve sitting in a chair
and moving one's eyes from side to side,
not while talking, but for me, you know,
and then recounting the event.
So it's sometimes talking while moving the eyes,
but usually it was moving the eyes from side to side
for 30, 60 seconds, then describing this challenging procedure.
Now, as a vision scientist who also works on stress,
when I first heard this, I thought it was crazy, frankly.
People would ask me about EMDR and I just thought, that's crazy.
I went and looked up some of the theories
about why EMDR might work.
And there were a bunch of theories,
oh, it mimics the eye movements during REM sleep, that was one.
Turns out that's not true and I'll explain why.
The other one was, oh, it synchronizes the activity
the two sides of the brain.
Well, sort of.
I mean, when you look into both sides
of the binocular visual field,
you activate the visual cortex,
but this whole idea of synchrony
between the two sides of the brain
is something that I think modern neuroscience
is starting to, let's just say,
gently or not so gently move away from
this whole right brain left brain business.
It turns out, however,
that I move into the sort that I just did
and that Francine Shapiro took from this walk experience
brought to her clients in the clinic
are the sorts of eye movements that you generate
whenever you're moving through space,
when you are self generating that movement.
So not so much when you're driving a car,
but certainly if you were riding a bicycle
or you were walking or you were running,
you don't realize it,
but you have these reflexive subconscious eye movements
that go from side to side
and they are associated with the motor system.
So when you move forward, your eyes go like this.
There have been a number of studies showing
that these lateralized eye movements
helped people move through or dissociate
the emotional experience of particular traumas
with those experiences such that they could recall
those experiences after the treatment
and not feel stressed about them
or they didn't report them as traumatic any longer.
Now the success rate wasn't 100%,
but they were statistically significant
in a number of studies.
And yet there are still some critics of EMDR
and frankly for a long time, I still thought,
well, I don't know, this just seems like kind of a half.
it just seems like kind of a,
something for which we don't know the mechanism
and we can't explain.
But in the last five years,
there have been no fewer than five,
and there's a sixth on the way,
high quality peer reviewed manuscripts
published in Journal of Neuroscience,
Neuron, Cell Press Journal, excellent journal,
nature, excellent journal.
These are very stringent journals and papers
showing that lateralized eye movements
of the sort that I just did
if you're just listening to this,
is just sweeping the eyes from side to side
with eyes open, that those eye movements,
but not vertical eye movements,
suppress the activity of the amygdala,
which is this brain region that is involved
in threat detection, stress, anxiety, and fear.
There are some forms of fear that are not amygdala dependent,
but the amygdala, it's not a fear center,
but it is critical for the fear response
and for the experience of anxiety.
So that's interesting.
We've got a clinical tool now
that indeed shows a lot of success
in a good number of people
where eye movements from side to side
are suppressing the amygdala
and the general theme is to use those eye movements
to suppress the fear response
and then to recount or repeat the experience
and over time uncouple the heavy emotional load,
the sadness, the depression, the anxiety,
the fear from whatever it was that happened
that was traumatic.
This is important to understand because I'd love to be able
to tell somebody who had a traumatic experience
that they would forget that experience.
But the truth is you never forget the traumatic experience.
What you do is you remove the emotional load.
Eventually it really does lose its potency.
The emotional potency is alleviated.
Now EMDR, I should just mention,
tends to be most successful for single event
or very specific kinds of trauma
that happened over and over.
as opposed to say an entire childhood
or an entire divorce.
They tend to be, it tends to be most effective
for single event kinds of things, car crashes, et cetera,
where people can really recall the events
in quite a lot of detail.
So it's not for everybody and it should be done,
if it's going to be done for trauma,
it should be done in a clinical setting
with somebody who's certified to do this.
But that bears a lot of resemblance to REM sleep, right?
This experience in our sleep where our eyes are moving,
moving, excuse me, although in a different way,
but we don't have the chemical epinephrine
in order to generate the fear response
and yet we're remembering the event from the previous day or days.
Sometimes in REM sleep, we think about things
that happened a long, long time ago.
So that's interesting.
And then now there's this new treatment,
this chemical treatment with the drug ketamine,
which also bears a lot of resemblance
to the sorts of things that happen in REM sleep.
Ketamine is getting a lot of
attention now and I think a lot of people just don't realize what ketamine is.
Ketamine is a dissociative anesthetic.
It is remarkably similar to the drug called PCP, which is certainly a hazardous drug for people
to use.
Ketamine and PCP both function to disrupt the activity of a particular receptor in the brain
called the NMDA receptor, N-Methyl D-D-A receptor, N-Methyl D.
be a spartate receptor.
This is a receptor that's in the surface of neurons
or on the surface of neurons for which most of the time
it's not active.
But when something very extreme happens
and there's a lot of activity in the neural pathway
that impinges on that receptor, it opens
and it allows the entry of molecules, ions,
that trigger a cellular process
that we call long-term potentiation.
long-term potentiation translates to a change in connectivity
so that later you don't need that intense event
for the neuron to become active again.
Let me clarify a little bit of this.
The NMDA receptor is gated by intense experience.
One way you can think about this is typically I walk in my home,
I might make some food and sit down at my kitchen table
and I don't think anything about explosions.
But were I to come home one night,
sit down to a bowl of chicken soup,
and there was a massive explosion,
the neurons that are associated with chicken soup
and my kitchen table would be active in a way
that was different than they were previously
and would be coupled to this experience of explosions
such that the next time and perhaps every other time
that I go to sit down at the kitchen table,
no matter how rational I am about the origins of that explosion,
maybe it was a gas truck that was down the road
and there's no reason to think it's there today,
but I would have the same experience.
Those neurons would become active,
and I'd get an increase in heart rate,
I'd get an increase in sweating, et cetera.
Ketamine blocks this NMDA receptor
and prevents that crossover and the addition of meaning
to the kitchen table, kitchen soup, explosion experience.
So how is ketamine being used?
Ketamine is being used to prevent learning of emotions
very soon after trauma.
So ketamine is being stocked
in a number of different emergency rooms
where if people are brought,
brought in quickly and these are hard to describe even,
but you know, a horrible experience of,
you know, somebody seeing a loved one next to them
killed in a car accident and they were driving that car.
This isn't for everybody certainly
and you need to talk to your physician,
but ketamine is being used
so they might infuse somebody with ketamine
so that their emotion is, it can still occur
but that the plasticity,
the change in the wiring of their brain
won't allow that intense emotion
to be attached to the experience.
Now immediately you can imagine the sort of ethical implications of this, right?
Because certain emotions need to be coupled to experiences.
I'm not saying that people should be using ketamine or shouldn't be using ketamine, certainly not recreationally.
It's quite dangerous.
It can be lethal and like PCP it can cause pretty dramatic changes in perception and behavior.
But in the clinical setting, the basis of ketamine assisted therapies is really to remove emotion.
And I think the way I've been hearing about it talked about in the general public is a lot of people think it's a little bit more like the kind of psilocybin trials or the MDMA trials where it's about becoming more emotional or getting in touch with a certain experience. Ketamine is about becoming dissociative or removed from the emotional component of experience. So now we have ketamine, which chemically blocks plasticity and prevents the connection between an emotion and an experience. That's a pharmacologic.
intervention. We have EMDR, which is this eye movement thing that is designed to suppress the
amygdala and is designed to remove emotionality while somebody recounts an experience. And we have
REM sleep where the chemical epinephrine that allows for signaling of intense emotion to and the
experience of a tense emotion in the brain and body is not allowed. And so we're starting to see a
organizational logic, which is that a certain component of our sleeping life is acting
like therapy. And that's really what REM sleep is about. So we should really think about REM sleep
and slow wave sleep as both critical slow wave sleep for motor learning and detailed learning,
REM sleep for attaching of emotions to particular experiences and then for making sure that
the emotions are not attached to the wrong experiences and for unlearning emotional responses
if they're too intense or severe. And this all speaks to the great importance of,
of mastering one's sleep,
something that we talked about in episode two of the podcast
and making sure that if life has disruptive events,
either due to travel or stress or changes in school
or food schedule, something that we talked about
in episodes three and four,
that one can still grab a hold and manage one's sleep life.
Because fundamentally, the unlearning of emotions
that are troubling to us is what allows
us to move forward in life. And indeed, the REM deprivation studies show that people become
hyper-emotional. They start to catastrophize. And it's no surprise, therefore, that sleep disturbances
correlate with so many emotional and psychological disturbances. It's just by now it should just be
obvious why that will be the case. In fact, the other day I was in a discussion with a colleague
of mine who's down in Australia, Dr. Sarah McKay. I've known her for two decades now from the time
she was at Oxford and Sarah studies,
among other things, menopause in the brain.
And she was saying that a lot of the emotional effects
of menopause actually are not directly related
to the hormones.
There have been some really nice studies showing
that the disruptions in temperature regulation
in menopause map to changes in sleep regulation
that then impact emotionality
and inability to correctly adjust the circuits related
to emotionality.
And I encourage you to look at her work.
We'll probably have her as a guest on the podcast
at some point in the future
because she's so knowledgeable about those sorts of issues
as well as issues related to testosterone
and in people with all sorts of different chromosomal backgrounds.
So sleep deprivation isn't just deprivation of energy.
It's not just deprivation of immune function.
It is deprivation of self-induced therapy
every time we go to sleep.
Okay, so these,
Things like EMDR and ketamine therapies are in clinic therapies,
but REM sleep is the one that you're giving yourself
every night when you go to sleep,
which raises, I think the other important question,
which is how to get and how to know
if you're getting the appropriate amount of REM sleep
and slow wave sleep.
So that's what we'll talk about next.
So how should one go about getting the appropriate amount
of slow wave sleep and REM sleep
and knowing that you're getting the right amount?
Well, short of hooking your sleep,
up to an EEG, it's gonna be tough to get exact measurements
of brain states from night to night.
Some people nowadays are using things like the aura ring
or a woup band or some other device
to measure the quality and depth and duration of their sleep.
And for many people, those devices can be quite useful.
Some people are only gauging their sleep by way
of whether or not they feel rested,
whether or not they feel like they're learning
and they're getting better or not.
There are some,
things that one can really do.
And the first one might surprise you
in light of everything I've said
and probably everything you've heard about sleep.
There was a study done by a Harvard undergraduate,
Emily Hoagland, who was in Robert Strickgold's lab
at the time.
And that study explored how variations
in total sleep time related to learning
as compared to
total sleep time itself.
And to summarize the study, what they found
was that it was more important to have a regular amount
of sleep each night as opposed to the total duration.
In other words, and what they showed was that improvements
in learning or deficits in learning
were more related to whether or not you got six hours, six hours,
five hours, six hours, six hours,
That was better than if somebody got, for instance,
six hours, 10 hours, seven hours, four or five hours.
So you might say, well, that's crazy
because I thought we're just all supposed to get more sleep
and there's more REM towards morning.
Turns out that for sake of learning new information
and performance on exams in particular,
that's what was measured,
limiting the variation in the amount of your sleep
is at least at least at,
as important and perhaps more important
than just getting more sleep overall.
And I think this will bring people great relief,
many people great relief,
who are struggling to quote unquote get enough sleep.
Remember a few episodes ago,
I talked about the difference between fatigue and insomnia.
You know, fatigue tends to be when we are tired,
insomnia tends to lead to a sleepiness during the day
when we're falling asleep.
And you don't want that.
You don't want either of those things really.
but I found it striking that the data from this study
really point to the fact that consistently getting
about the same amount of sleep is better
than just getting more sleep.
And I think nowadays so many people are just aiming
for more sleep and they're rather troubled about the fact
that they're only getting five hours
or they're only getting six hours in some cases.
It may be the case that they are sleep deprived
and they need more sleep,
but some people just have a lower sleep need
And I find great relief personally in the fact
that consistently getting for me about six hours
or six and a half hours is going to be more beneficial
than constantly striving for eight or nine
and finding that some nights I'm getting five
and sometimes I'm getting nine
and varying around the mean.
As I recall and I think I'm gonna get this precisely right
but if not I know that I'm at least close
for every hour variation in sleep,
regardless of whether or not I was more sleep
than one typically got, there was a,
17% reduction in performance on this particular exam type.
And so this is powerful.
This means that we should strive for a regular amount of sleep.
And for some of us, that means falling asleep
and waking up and going back to sleep.
For some people, it means falling asleep
and waking up and not getting back to sleep.
Now, ideally you're getting the full complement
of slow wave sleep early in night
and sleep toward morning, which is REM sleep,
which brings us to how to get more REM sleep.
Well, they're going to,
a couple of different ways,
but here's how to not get more REM sleep.
All right?
First of all, drink a lot of fluid right before going to sleep.
One of the reasons why we wake up
in the middle of the night to use the bathroom
is because when our bladder is full,
there is a neural connection,
literally a set of neurons and a nerve circuit
that goes to the brainstem that wakes us up.
And actually some people that I know
and won't be mentioned actually use this
to try and adjust.
for their jet lag when they're trying to stay awake.
Having to use the bathroom, having to urinate
is one of the most anxiety evoking experiences anyone can have.
If you really have to go to the bathroom,
it's very hard to fall asleep or stay asleep.
And bedwetting, which happens in kids very early on,
is a failure of those circuits to mature
until, you know, I think we all assume
that babies are gonna pee in their sleep,
but adults aren't supposed to do that.
And the circuit,
it takes some time to develop
and in some kids they develop a little bit later than others.
So having a full bladder is one way to disrupt your sleep.
You don't wanna go to bed dehydrated,
but that's one way.
On the other hand, there is evidence
that if you want to remember your dreams more
or remember more of your dreams,
there is a tool that you can use.
I don't necessarily recommend it,
which is to drink a bunch of water before you go to sleep.
And then what happens is you tend to break
in and out of REM sleep.
It tends to be fractured.
And with,
the sleep journal, then they've done these laboratory studies, believe it or not, people will
recall more of their dreams because they're in this kind of semi-conscious state because they're
constantly waking up throughout the night. I suggest not having a full bladder before you go to
sleep. That one's kind of an obvious one, but nonetheless. The other one is if you recall
that during REM sleep, we have a shift in neurotransmitters such that we have less serotonin,
right, just wanna make sure I got that right.
Excuse me, less serotonin.
There are a lot of supplements out there
geared toward improving sleep.
I've taken some of them and I'm taking many of them,
if not all of them at this point,
so I could report back to you.
And I think I mentioned on a previous episode
that when I take tryptophan or anything that contains 5HTP,
which is serotonin or a precursor to serotonin,
serotonin is made from triptophan,
I tend to fall very deeply asleep
and then wake up a few hours.
later and that makes sense now based on the fact
that you just don't want a lot of REM sleep early on.
What was probably happening is that I was getting
a lot of REM sleep early on because low levels
of serotonin are typically associated with slow wave sleep
and that comes early in the night.
So for some people those supplements might work
but beware serotonin supplements could disrupt
the timing of REM sleep and slow wave sleep
and in my case led to waking up very shortly
after going to sleep and not being able to get back to sleep.
Now, if you want to increase your slow wave sleep, that's interesting.
There are ways to do that.
One of the most powerful ways to increase slow wave sleep, the percentage of slow wave sleep,
apparently without any disruption to the other components of sleep and learning,
is to engage in resistance exercise.
It's pretty clear that resistance exercise triggers a number of metabolic and endocrine pathways
that lend themselves to release of growth hormone, which happens early in the next.
night. And resistance exercise, therefore, can induce a greater percentage of slow wave sleep.
It doesn't have to be done very close to going to bedtime. In fact, for some people that the exercise
can be disruptive for reasons I've talked about in previous episodes. But resistance exercise,
unlike aerobic exercise, does seem to increase the amount of slow wave sleep, which, as we know,
is involved in motor learning and the acquisition of fine detailed information, not general rules
or the emotional components of experiences.
For those of you that are interested in lucid dreaming
and would like to increase the amount of lucid dreaming
that you're experiencing,
I haven't been able to track down that device
with the red light that I described at the beginning,
but there are a number of just simple zero technology tools
that one could use in principle.
One is to set a cue.
The way this works is you come up with a simple statement
about something that you'd like to see or experience later in dreams.
You can, for instance, write down something like,
I want to remember the red apple.
I know it sounds silly and trivial.
And you look at that, you would probably want to write it down on a piece of paper.
You might even want to draw a red apple.
And then before you go to sleep, you would look at it.
And then you would just go to sleep.
There are some reports that doing that,
for several days in a row can lead to a situation
in which you are suddenly in your dream
and you remember the red apple
and that gives you a sort of tether to reality
between the dream state and reality
that allows you to navigate and shape
and kind of adjust your dreams.
Lucid dreaming does not have to be
or include the ability to alter features of the dream.
You know, to be able to control things in the dream.
Sometimes it's just the awareness that you are dreaming.
But nonetheless, some people enjoy lucid dreaming
And then for people that have a lot of lucid dreams
that feel kind of overwhelmed by those,
that's going to involve trying to embrace protocols
that can set the right duration of sleep.
There's a little bit of literature, not a lot,
that shows that keeping the total amount of sleep per night
to say six hours such that you begin sleep and end
at the beginning and end of one of these ultradian cycles
can be better than waking up in the middle
one of these ultradian cycles.
So try and find the right amount of sleep
that you need that's right for you
and then try and get that consistently night tonight.
If you're a lucid dreamer and you don't like it,
then you may want to start to make sure
that you're waking up at the end
of one of these ultradian cycles.
So in this case, it would be better to wake up
after six hours than after seven.
And if you did sleep longer than six hours,
maybe you'd wanna get to seven and a half hours
because that's gonna reflect the end
of one of these 90 minute cycles
as opposed to waking up
the middle. Alcohol. Alcohol and marijuana are well known to induce states that are pseudo sleep
like, especially when people fall asleep after having consumed alcohol or THC, the active component,
one of the active components in marijuana. Alcohol, THC, and most things like them, meaning things that
increase serotonin or GABA are going to disrupt the pattern of sleep.
They're going to disrupt the depth.
They're going to disrupt the overall sequencing
of more slow wave sleep early in the night
and more REM sleep later in the night.
That's just the reality.
There are some things that, at least in a few studies
that I could find, seem to suggest that you could increase
the amount of slow wave sleep using things like arginine,
the amino acid al-arginine, although you really want to check.
Arginine can have effects on heart, et cetera,
has other effects.
But alcohol, THC, not gonna be great for sleep
in depth of sleep.
You might feel like you can fall asleep faster,
but the sleep that you're accessing
really isn't the kind of deep restorative sleep
that you should be getting.
Now of course, if that's what you need in order to sleep
and that's within your protocols, as I've said here before,
I'm not suggesting people taking anything.
I'm not a medical doctor, I'm not a cop,
so I'm not trying to regulate anyone's behavior.
I'm just telling you what the literature says.
Some of you may want to explore your dreams
and meaning of dreams, et cetera.
You know, there's not a lot of hard data
about how to do.
this, but a lot of people report keeping a sleep journal
where a dream journal can be very useful.
So they mark when they think they fell asleep the night before,
when they woke up.
And if they wake up in the middle of the night,
early in the morning, they'll just write down
what they can recall of their dreams.
And even if they recall nothing,
many people have the experience of mid-morning or later afternoon
that suddenly comes to them that they had a dream
about something and writing that down.
I kept a dream journal for a while.
It didn't really afford me much.
I didn't really learn anything except that my dreams were very bizarre.
But there are some things that happen in dreams
that are associated with REM sleep as it compared to slow wave sleep,
which can tell you whether or not your dream likely happened
in REM sleep or slow wave sleep.
And the distinguishing feature, it turns out,
is something called theory of mind.
Theory of mind is actually an idea that was developed
for the study and assessment of autism.
And it was initially that phrase theory of mind
was brought about
by Simon Baron Cohen,
who is Sasha Baron Cohen, the comedian's brother.
Simon Baron Cohen is a psychologist
and to some extent a neuroscientist at Oxford.
And theory of mind tests are done on children.
And the theory of mind test is some, like the following.
A child is brought into a laboratory
and watches a video of a child playing with some sort of toy.
And then at the end of playing with that,
toy, they put the toy in a drawer and they go away. And then another child comes in and is looking
around and then the experimenter asks the child who's in the experiment, the real child and says,
you know, what does the child think? You know, what are they feeling? And most children of a
particular age, five or six or older will say, oh, you know, he or she is confused. They don't
know where the toy is or they'll say something that implies what we call theory of mind,
that they can put their ideas into and their mind into what the other child is likely to be
feeling or experiencing. That's theory of mind. And it turns out that this is used as one of the
assessments for autism because some children, not all, but some children that have autism or that go
on to develop autism don't have this theory of mind. They tend to fixate on the fact that the first
child put the toy in the drawer, they'll say it's in the drawer, as opposed to answering the
question, which is how does the second child feel about it or what are they experiencing?
So theory of mind is something that emerges early in life as a part of the maturation of the
circuits in the brain associated with emotional learning and social interactions. And we experience
this in certain dreams. So if you had a dream that you're puzzled about or that you're fixated on
and you're thinking about, you might ask,
in that dream, was I assessing somebody else's emotion and feeling?
Or was I very much in my own first person experience?
And the tendency is that theory of mind
tends to show up most in these REM associated dreams.
Now this isn't a hard and fast rule,
but chances are if you were in a dream
and you were thinking about other people
who wanted to do something to you,
you were thinking about their desire
to chase you or help,
you or something that was related to someone else's emotional experience, it was probably a
REM dream. That dream occurred in rapid eye movement sleep as opposed to slow wave sleep.
And that makes sense when you think about the role of REM in emotional unlearning of associations
with particular life events, that REM is rich with all sorts of exploration of the emotional
load of being chased or the emotional load of having to take an example.
the next day or being late for something.
But again, if you're fixated or you can recall
thinking a lot about or feeling a lot about
what somebody else's motivations were,
then chances are it was in REM.
And if not, chances are it was in slow wave sleep.
Today we've been in a deep dive of sleep and dreaming,
learning and unlearning.
And I just wanna recap a few of the highlights
and important points.
A lot more slow wave sleep and less,
REM early in the night, more REM and less slow wave sleep later in the night.
REM sleep is associated with intense experiences without this chemical epinephrine that
allows us the anxiety or fear and almost certainly has an important role in uncoupling of
emotion from experiences, kind of self-induced therapy that we go into each night.
That bears striking resemblance to things like EMDR and ketamine therapies and so forth.
Slow wave sleep is critical, however.
It's critical mostly for motor learning
and the learning of specific details.
So REM is kind of emotions and general themes
and meaning and slow wave sleep, motor learning and details.
I personally find it fascinating that consistency of sleep,
meaning getting six hours every night
is better than getting 10 one night,
eight the next, five the next, four the next.
I find that fascinating,
and I think I also like it because it's something
I can control better than just trying to sleep more,
which I think I'm not alone and agreeing
that that's just hard for a lot of people to do.
This episode also brings us to the conclusion
of a five episode streak where we've been focusing
on sleep and transitions in and out of sleep,
non-sleep depressed.
We've talked about a lot of tools, morning light,
evening light, avoiding lights, blue blockers, supplements,
tools for measuring sleep duration and quality,
we've been covering a lot of themes.
I like to think that by now you're armed
with a number of tools and information,
things like knowing when your temperature minimum is,
knowing when you might wanna view light or not,
when you might wanna eat or take hot showers
or God forbid a cold shower,
something that most people including me more or less loathe
but can have certain benefits.
And that will allow you to shape your sleep life
and get this consistent or more or less consistent
amount of sleep on a regular basis.
Nobody's perfect.
In fact, I have this little joke that I sometimes tell it's not funny.
Like most of the jokes I tell I'm told they're not funny,
but there's so much excitement now about intermittent fasting.
Sometimes I think that someone should start something
on intermittent sleep deprivation,
although we're already doing that.
We are all experiencing lack of sleep from time to time.
And I don't think we should catastrophize that too much.
I think that what we wanna do,
rather than accumulate a sleep anxiety is to,
you know, if we get a bad night's sleep,
we want to adjust,
We want to get back on track
and just get the consistent amount of sleep.
Use those non-sleep deep rest protocols
to help us relax when we're feeling anxious.
We're having trouble waking up in the middle of the night.
There are a lot of tools out there.
And most of them are zero cost.
And so I hope you'll find those beneficial.
If you've been hearing Costello snoring
throughout this episode, I apologize in his behalf.
As I said in the welcome video to this podcast,
he's an integral part of the podcast.
A few people have said, hey,
that noise in the background is really disruptive.
Hey, what can I say?
Costello is a 10 year old bulldog mastiff.
The lifespan on those animals is about 10 years.
So I'm not trying to make you feel guilty,
but after he's gone, there won't be any snoring,
although I'll probably get a different dog.
So sort of a, what would the kids say?
Sorry, not sorry.
Sorry not sorry about the snoring.
And I'm sorry if it's disruptive, genuinely,
but he's here for the hall.
So that's what that's about.
As we close out this segment on sleep,
we are moving into a new theme and topic
for the next four to five episodes.
We are going to discuss the science
and the tools related to neuroplasticity.
Neuplasticity is a remarkable feature of the nervous system.
In fact, it's the defining feature of the nervous system,
which is its ability to change itself
in response to experience.
That is unlike every other tissue
and collection of cells and organ in our body.
It's really what makes
us as a species and it's what makes us us as individuals and it's really where our potential
lies. Everything that we know, everything we can do and our true potential in terms of what we will
ever be able to know, do, say in life is set by the limits of neuroplasticity. So we're going to explore
learning in childhood, learning in adulthood. We're going to discuss detailed protocols as they relate
to sensory plasticity, learning new sensory information
versus motor plasticity or sensory motor integration.
We're going to talk about language acquisition.
We're going to be talking about emotional acquisition
and breadth as well as I think a topic,
a lot of people are gonna find fascinating
is the relationship between plasticity set
during childhood attachment to parent or other caregiver
and how that maps onto adult relationships.
You know, there's many of you have probably heard
about secure attached or insecure,
the AB and C babies as they're called
from the classic studies of Bolby and others.
But now there's actual neuroscience that can say
which circuits were active during those early life attachments
and how those map to adult attachment styles, challenges,
and what makes us more likely to select certain partners
and styles of attachment as well as how to change those.
It's really fascinating and I think neuroscience time
has come for neuroplasticity.
We're also gonna talk of course
about supplements and chemicals and machines
and devices that can assist in speeding up
the plasticity process.
Or believe or not, there are some cases
where you might want to delay plasticity
in order to get more depth of learning
and have that learning last longer,
something that is just absolutely spectacular literature.
So I'm very excited to move on to that topic soon.
I hope that the tools that you've acquired so far
and the knowledge that you've acquired so far
is helping you with yourself evaluation
and experimentation as you see.
fit and is allowing you to not just sleep better,
but feel better while you're awake
and hopefully has set the stage for you to learn better
as we start to march into the month on neuroplasticity.
Many of you have asked how you can help support
the Huberman Lab podcast and we greatly appreciate the question.
You can help support the podcast by subscribing
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Last but not least, a few people wrote to me
with some questions,
slash corrections about things that I said
in previous podcast.
So in keeping with my goal of making the information accurate
and clear, I just want to correct myself
about a few things that I said.
One of those, and I'm guessing it probably came
from an endocrinologist or somebody else
that knows a lot about testicles said,
Huberman, you mentioned that testosterone
is made by the Sertoli cells of the testes
and it's not, it's made by the Lydig cells of the testes,
the testes and indeed you are correct.
And so I want to make sure that I clarify that.
Testosterone is made by the Lydic cells of the testes,
not by the Sertoli cells.
The Sertoli cells make five alpha reductase
and aromatase and some other enzymes involved
in conversion of testosterone into things like DHD and estrogen.
So thank you for that correction.
I genuinely appreciate it.
I misspoke.
The other thing I said was at one point I said,
typical temperature is 96.8 when I actually meant to say 98.6.
So it was a dyslexic slip on my part,
and I apologize, I don't know that I'm dyslexic.
I know I'm being clinically diagnosed with dyslexia,
but I swapped them, which sometimes happens when I'm going fast.
So I apologize, I'll use this as a moment to just say,
temperature varies a lot across the day and night.
That was a theme of previous podcast.
So we can't really talk about average temperature anyway,
but I do wanna be clear that most people think
about average temperature as 98.6.
I misspoke.
my error and I apologize.
Thank you for joining me in this journey
of the nervous system in biology
and trying to understand the mechanisms
that make us who we are
and how we function in sleep and in wakefulness.
It's really an incredible landscape to consider
and I hope that you're getting a lot out of the information.
As always, thank you for your interest in science.