Huberman Lab - Use Sleep to Enhance Learning, Memory & Emotional State | Dr. Gina Poe
Episode Date: February 13, 2023My guest this episode is Gina Poe, PhD, a professor in the department of integrative biology & physiology at the University of California, Los Angeles (UCLA). We discuss her research exploring how sle...ep impacts learning, memory, hormones and emotions. She discusses tools to enhance your quality of sleep, increase deep sleep, rapid eye movement sleep and growth hormone release-- a key hormone for health, immune function and vitality. Dr. Poe explains how a specific brain area, the locus coeruleus, facilitates the processing of emotions, helps relieve traumas and how to maximize locus coeruleus function. She also explains sleep’s vital role in opiate addiction recovery and how anyone can determine their optimal sleep timing and duration. This episode is rich with basic science information and zero-cost tools to enhance quality and effectiveness of sleep for sake of mental health, physical health and performance. For the full show notes, visit hubermanlab.com. Thank you to our sponsors AG1: https://athleticgreens.com/huberman LMNT: https://drinklmnt.com/hubermanlab Waking Up: https://wakingup.com/huberman Momentous: https://livemomentous.com/huberman Timestamps (00:00:00) Dr. Gina Poe (00:02:52) Sponsor: LMNT (00:06:58) Sleep Phases, Perfect Night’s Sleep (00:10:32) Can You Oversleep? (00:14:50) Sleep Cycles, Sleep Spindles, “Falling” Asleep, Dreams & Memories (00:19:01) Tool: Growth Hormone Release & Sleep (00:22:05) Adolescence; Early Sleep, Alcohol & Sleep Spindles (00:24:55) Middle Sleep States & REM, Schema, Waking at Night (00:30:33) Deep Sleep, Dreams & Senses (00:33:22) Sponsor: AG1 (00:34:37) Later Sleep, Paralysis, Sleepwalking, Sleep Talking (00:36:47) Alarm Clock & Grogginess; Sleep Trackers, Brain & Sleep (00:43:19) Early Slow Wave Sleep & “Washout”, Normal Sleep Cycle & Night Owls (00:54:30) Locus Coeruleus, Learning & REM Sleep (01:01:46) Post-Traumatic Stress Disorder (PTSD), Locus Coeruleus & Sleep (01:07:31) Locus Coeruleus, Trauma & Sleep, Antidepressants, Norepinephrine (01:12:29) Locus Coeruleus, Bedtime & Novelty, Estrogen & Trauma (01:16:22)Sex Differences & Sleep (01:19:12) Tool: Non-Sleep Deep Rest (NSDR), Insomnia, Meditation, Prayer (01:27:42) Sleep Spindles, Learning & Creativity, P Waves & Dreaming (01:34:51) Lucid Dreams, Reoccurring Dreams, Trauma (01:44:11) Trauma Recovery, Locus Coeruleus & Norepinephrine, REM Sleep (01:52:15) Opiates, Addiction, Relapse & Sleep (02:02:45) Zero-Cost Support, Spotify & Apple Reviews, YouTube Feedback, Sponsors, Momentous, Neural Network Newsletter, Social Media Disclaimer Learn more about your ad choices. Visit megaphone.fm/adchoices
Transcript
Discussion (0)
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.
Today my guest is Dr. Gina Poe.
Dr. Gina Poe is a professor in the Department
of Integrative Biology and Physiology
at the University of California, Los Angeles.
Her laboratory and research focuses on the relationship
between sleep and learning.
In particular, how specific patterns of brain activity
that are present during specific phases of sleep,
impact our ability to learn and remember specific types of information.
For instance, procedural information,
that is how to perform specific cognitive or physical tasks,
as well as encoding of emotional memories
and discarding emotional memories.
Indeed, her research focuses on how specific phases of sleep
can act as its own form of trauma therapy,
discarding the emotional tones of memories.
In addition, her laboratory focuses on how specific phases of sleep,
sleep impact things like the release of growth hormone.
Growth hormone, of course, plays critical roles in metabolism and tissue repair,
including brain tissue repair, and therefore has critical roles in vitality and longevity.
Today you will learn many things about the relationship between sleep, learning,
emotionality, and growth hormone.
One basic but very important takeaway that you'll learn about today, which was news to me,
is that it's not just the duration and depth of your sleep that matter,
but actually getting to sleep at relatively the same time.
each night ensures that you get adequate growth hormone release in the first hours of sleep.
In fact, if you require, let's say, eight hours of sleep per night, but you go to sleep two
hours later than your typical bedtime on any given night, you actually miss the window for
growth hormone release. That's right. Getting growth hormone release in sleep, which is absolutely
critical to our immediate and long-term health, is not a prerequisite of getting sleep,
even if we are getting enough sleep. As Dr. Poe explains, they're critical brain circuits,
and endocrine, that is hormone circuits that regulate not just the duration and depth and quality
and timing of sleep, but when we place our bout of sleep, that is when we go to sleep each night,
plus or minus about a half hour or so, strongly dictates whether or not we will experience
all the health promoting, including mind promoting benefits of sleep.
Today's episode covers that and a lot more in substantial detail.
You will learn, for instance, how to use sleep in order to optimize learning as well as forgetting
for those things that you would like to forget.
So during today's episode, Dr. Genopo shares critical information about not just neuroscience,
but physiology and the hormone systems of the brain and body that strongly informant
mental health, physical health, and performance.
So by the end of today's episode, you'll be far more informed about sleep and how it works,
the different roles it performs, and you'll have several new actionable steps that you can take
in order to improve your mental health, physical health, and performance.
Before we begin, I'd like to emphasize that this podcast is separate from my teaching and research roles at Stanford.
It is, however, part of my desire and effort to bring zero cost to consumer information
about science and science-related tools to the general public.
In keeping with that theme, I'd like to thank the sponsors of today's podcast.
And now for my discussion with Dr. Gina Poe.
Dr. Gina Poe, welcome.
Thank you.
I've really been looking forward to this conversation because I'm familiar with your work,
and I know that many people are going to be excited to learn about your work as it relates to sleep,
as it relates to problem-solving, creativity.
addiction and craving, relapse, and a number of other important topics.
So to start things off, I would love for you to educate us a bit about this thing that we are all
familiar with and yet very few of us understand, which is sleep.
And if you would, could you describe the various phases of sleep that exist, what distinguish
them, and perhaps frame this within the context of what would a perfect night's sleep look like?
Okay.
How long would it last, more or less?
And what would the biology look like?
What is a perfect night's sleep?
Oh, yeah, that's a great question.
All right.
So sleep is really different from wakefulness.
And in fact, can't be replaced by any state of wakefulness that we've been able to come up with so far.
Our brain chemistry is completely different.
And in the different stages of sleep, which there are non-REM and REM are the two major states of sleep.
And every animal we've studied so far seems to have both of those states.
Anyway, those two states are entirely different from one another, too.
And even within non-REM, there are three states.
Stage one, which is what you slip into when you first falling asleep.
It's dozing.
There's kind of an interesting rhythm that goes on in the brain.
It's kind of a fast gamma rhythm.
And then there's stage two, which is a really cool state.
We sort of used to ignore sleep researchers because it was a transient state
between wakefulness and the deep stage three slow-wave sleep,
which is the most impressively different.
And then, and between that and REM sleep.
So stage two, I'll talk a little bit more about.
And then the deep slow wave sleep state, which is when big slow waves sweep through our brain.
And now we realize that it cleans our brain.
One of the things that those big slow waves do is cleans our brain and does other really important things to restore us from a day of wakefulness.
And then REM sleep, which is the most popular because that's where we have the most active dreams.
and when you wake up someone out of REM sleep, they'll almost always report having dreamed something really bizarre.
That's called REM sleep, rapid eye movement sleep.
So those are the four states of sleep, of human sleep, and we cycle through them every 90 minutes or so.
When we go to sleep, say 10, 10, 30, 11 o'clock, our first REM sleep period comes about 105 minutes after we fall asleep and lasts about 20 minutes.
Actually, it comes about 95 minutes in last 10 or 15 minutes.
And then we start over again.
And we have about five of those per night for a perfect night's sleep, four or five, something like that.
So a perfect night sleep is seven, a half, eight hours.
There was a really great study that put people in a semi-darkened room with nothing but the bed for 12 hours every day for a month.
And what people did initially is because we're in a sleep-deprived nation,
that they slept a lot more than usual, like 10 or 11 hours of the 12.
And then they leveled off after a week or two to about eight hours and 15 minutes of sleep.
So you actually can't oversleep.
I mean, they had nothing else to do but sleep.
And they would round off to on average eight hours and 15 minutes a night.
And then they spend the rest of the time twiddling their thumbs, humming tunes, you know, daydreaming.
I want to get back to the contour of a perfect night's sleep.
But I'm intrigued by this idea that people can't oversleep.
I'm often asked whether or not we can get too much sleep and whether or not sleeping too long,
excuse me, can make us groggy the next day.
Is there anything to that?
And how does one determine how long they should sleep on average?
On average, yeah.
Well, that's interesting because different people seem to need different amounts of sleep.
But we don't really even know exactly what sleep is for.
So what they need is, you know, kind of, it's, you know, murky.
So we do know a lot of things that sleep does now for us,
but we don't know how long those things take.
So how long we need to sleep is also just a big question mark.
But some people don't feel rested until they've slept nine hours.
And some people don't feel rested after three or four and a half.
But most people, if they consistently deprive themselves of sleep so that they're only sleeping four,
four and a half hours a night, build up a cognitive deficit that just builds up over time.
The more nights you have with sleep deprivation, the more cognitive deficit you have.
And so you need sleep, again, to sleep more to recover.
Now, the question you had about...
Can you over sleep?
Can you sleep to the point where it's too much?
You know, that we, I growing up when I was in high school, my girlfriend's dad had this belief
that no one should sleep in past 6 a.m. So he would wake all the, there were two children
in that home, he would wake up the kids in that house. He had this thing against oversleeping,
regardless of when people went to sleep. And I always thought that was an interesting mentality.
Yeah. It's not terrible actually because what that will do is it'll put you, make you sleep
you're the next night to get to bed on time. So it'll build up your homeostatic need if you wake up
too early. But so I don't think you can oversleep, but people who sleep a lot, like people
who sleep over nine hours, it's probably indicative of some other problem because in fact,
if you have a lot of different conditions, it will cause you to sleep a lot more, probably because
what it does is it interferes with your efficient sleep, the efficiency of your sleep. So
So if you find yourself sleeping consistently nine hours plus every night, then you might want to
consult a doctor about maybe what else it might be.
It could be cancer.
It could be sleep apnea.
That affects a lot of people.
It could be that your sleep is super inefficient because you're snoring a lot more than you
know or you're waking up a lot more than you know every night.
So you might want to sleep study just to see how your sleep is and then see what else might be
causing you to sleep so much. And that wouldn't be if somebody is sleeping nine or 10 hours,
you know, every once in a while. You mean if they're consistently sleeping for more than nine hours?
If they feel like they needed in order to function cognitively the next day,
it might be that your sleep is just not efficient and you might want to look into why that
that's the case. Interesting. Forgive me for the anecdote, but I can't resist. Years ago,
I went to an acupuncturist and he gave me these red pills of which I did.
don't know what they contained. But I took them because he told me they would help with my sleep.
And I would fall asleep about 30 minutes after taking them. And I would have incredibly,
vivid dreams. And I'd wake up four or five hours after having gone to sleep, feeling completely
rested, something that I've never really experienced on a consistent basis. I want to do mass spec
on these pills. I still have no idea what was in them whatsoever. I want to do mass spec on those pills.
Exactly. Some people have thought that perhaps they had GHB.
gamma hydroxybutyrate, which is, by the way, an illegal drug. It can kill you. It's not a, not something
you want to take. No, that's not good. But anyway, if ever someone can figure out what the red pills
were, I'll be very, and this is not a red pill of the other sort red pill. This is just the red
sleep pills. Interesting. I mean, could have been even a placebo effect, because placebo is
extremely strong. Although, I don't know, there was really something to these red pills.
So shout out to the acupuncturists and the Eastern medicine.
But to return to this idea of the architecture of a perfect night's sleep.
So you said, we fall asleep, the first 90 minutes of sleep, REM sleep, rapid eye movement
sleep will arrive at about 95 minutes in.
Does that mean that the rest of that 90 minutes is consumed with slow wave sleep?
Yeah, non-REM sleep.
And what about the sleep where we are lightly asleep?
And we might have a dream that has us somehow thinking about moving.
or that we jolt ourselves awake.
That often happens early in the night.
Yeah, yeah, that's the first stage, stage one
and stage two of sleep.
And stage two of sleep is really cool
because that has something called sleep spindles
and K complexes.
And what sleep spindles are a little bit of activity
that's 10 to 15 hertz in frequency.
It's a conversation between the thalamus and the cortex.
The gal thalamus is the gateway to consciousness
and the neocortex processes all our cognition.
And so it's these spindles, they're called sleep spindles.
And if you wake up out of that state,
you will often report a dream, like a hallucination style dream.
It won't be a long dream report like you have out of REM sleep,
but it will be some hallucination state.
During, while we're falling asleep,
one of the reason we call it falling asleep
is because in stage one and stage two,
our muscles are relaxing.
And if there's part of our brain that's conscious enough to sort of recognize that relaxation,
we'll feel like we're falling and will jerk awake.
So often that hallucination, it's called hypnagogic hallucination, will feel like it'll include
some falling aspect that we'll wake up out of.
That's really interesting to me.
I've long felt that sensation of almost like dropping back into my head.
So much so that if I elevate my feet just slightly and I tilt my feet.
head back just slightly in order to go to sleep, I find that I fall asleep much much faster.
Interesting.
But it does feel as if I'm going to fall like almost going to do a backwards somersault.
That's fascinating.
I actually really like the sensation.
And usually because it proceeds falling deeply asleep.
Yeah, that's really interesting.
Somebody has to do a study of elevated feet and...
Yeah, there's a little bit on body position and sleep and some of the washout that we'll talk about.
So early in the night, you've got these lighter stages of sleep, less rapid eye movement sleep.
sleep. What can we say about the dreams that occur during the, say, first and second, you know,
90-minute cycles of sleep? Are they quite different than the patterns of sleep and dreaming that
occur later in the night or toward morning? Well, okay, that's an interesting question. There's a lot of
facets to it. There is some evidence that the first four hours of sleep are very important
for memory processing.
And in fact, if you've learned something new that day
or have experienced a new sensory motor experience,
then your early sleep dreams will incorporate that experience
much more than the later sleep dreams.
Later as that memory gets consolidated from the early structures,
which are the hippocampus deep in the temporal lobe
to the cortex in a distributed fashion,
that memory seems to move from that hippocampus to the cortex and also the dreams that incorporate that memory also move later in the night.
So nobody knows why, but there was a great study by Sidarto Ribeiro, who studied the consolidation of memories from the cortex,
from the hippocampus to the cortex in a rat across the period of a full day sleep because rats sleep in the daytime.
And he found that each subsequent REM sleep period moved that memory from the hippocampus
to the first area that projects to it, and then the second area, and then the third area.
And you can see the memory moving throughout the sleep period.
Yeah.
Very cool.
So I have to read that study.
So there's a number of different hormones associated with the different stages of sleep.
We know that melatonin is a hormone of nighttime.
of nighttime that makes us sleepy.
What about growth hormone release?
When does that occur during sleep?
So growth hormone release happens all day long and all night long, but the deep slow-wave sleep
that you get, the very first sleep cycle is when you get a big bolus of growth hormone
release and in men and women equally.
And if you miss that first deep slow-wave sleep period, you also miss that big bolus of
growth hormone release.
And you might get ultimately across the day just as much overall growth hormone release,
but endocrinologists will tell you that big boluses do different things than a little bit eeked out over time.
So that is, well, we know there's also a big push to synthesize proteins.
So that's when the protein synthesis part that builds memories, for example, in our brain happens in that first cycle of sleep.
So you don't want to miss that, especially if you've learned something really big and needs more synaptic space to encode it.
How would somebody miss that first 90 minutes?
Sleep depriving themselves.
Yeah.
So let's say I normally go to sleep at 10 p.m.
And then from 10 to 1130 would be this first phase of sleep.
And that's when the big bolus of growth hormone would be released.
Does that mean that if I go to sleep instead at 1130 or midnight that I miss that first phase of sleep?
Yeah.
Why is it not the case that I get that first phase of sleep just simply starting later?
It is a beautiful clock that we have in our body that knows when things should happen.
And it's every cell in our body has a clock.
And all those clocks are normally synchronized.
And those circadian clocks are synchronized.
And so our cells are ready to respond to that growth hormone release at a particular time.
And if we miss it, and it's a time in relation to melatonin also,
So if you miss it, yeah, you might get some growth hormone release, but it's occurring at a time when
your clock has already moved to the next phase.
And so it's just a clock thing.
Yeah, I don't think we can overstate the importance of what you just described.
And to be honest, despite knowing a bit about the sleep research in circadian biology,
this is the very first time that I've ever heard this, that if you normally go to sleep at a
particular time and growth hormone is released in that first phase of sleep, that you can't
simply initiate your sleep bout later and expect to capture that first phase of sleep.
Yeah.
That's incredible and I think important.
And as many listeners are probably realizing, also highly actionable.
So what this means is that we should have fairly consistent bedtimes in addition to fairly
consistent wake times.
Is that right?
Exactly.
And in fact, one of the best markers of good neurological health when we get older is consistent
bedtimes.
Wow.
Okay.
I don't want to backtrack, but I did write down something that I think is important for me to resolve or for you to resolve.
So I'm going to ask this people that sleep nine hours or more, perhaps that reflecting an issue, some underlying issue, perhaps, is being a teenager or an adolescent and undergoing a stage of development where there's a lot of bodily and brain growth and exception to that?
Because I don't recall sleeping a ton when I was a teenager.
I had a ton of energy, but I know a few teenagers, and they sleep a lot.
Like they'll just sleep and sleep and sleep and sleep.
Should we let them sleep and sleep and sleep?
Okay. So that's the one exception.
What about us?
Just like babies.
Okay.
When you're developing something in your brain or the rest of your body, you really need
sleep to help organize that.
I mean, sleep is doing really hard work in organizing our brains and making it develop
right.
And if we deprive ourselves of sleep, we will actually.
also just like I said we have a daily clock. We also have a developmental clock and we can miss
a developmental window if we don't let ourselves sleep extra like we need to. What other things inhibit
growth hormone release or other components of this first stage of sleep? In other words, if I go to
sleep religiously every night at 10 p.m., are there things that I perhaps do in the preceding
hours of the preceding day like ingest caffeine or alcohol that can make that first stage of sleep
less effective, even if I'm going to sleep at the same time?
Alcohol definitely will do that, because alcohol is a REM sleep suppressant,
and it even suppresses some of that stage two transition to REM with those sleep spindles.
And those sleep spindles, we didn't talk about their function yet,
but they're really important for moving memories to our cortex.
It's a unique time when our hippocampus, sort of like the ram of our brains,
writes it to a hard disk, which is the cortex.
and it's a unique time when they're connected.
So if you don't want to miss that, you don't want to miss REM sleep
when it is also a part of a consolidation process
and schema-changing process.
And alcohol in there, you know, before we go to sleep, we'll do that.
Until we've metabolized alcohol and put it out of our bodies,
it will affect our sleep badly.
So probably fair to say no ingestion of alcohol
within the four to six hours preceding sleep?
given the half-life, or at all, or at all would be better, but I know some people refuse to go that
way.
And maybe a little bit is okay.
I don't know what the dose response is, but there are studies out there you can look at.
Great.
So we're still in the first stage of sleep, and I apologize for slowing us down, but it sounds
like it's an incredibly important first phase of sleep.
What about the second and third 90-minute blocks of sleep?
Is there anything that makes those unique?
What is their signature besides the fact that they come second and third in the night?
There's more and more REM sleep the later the night we get.
There's also a change in hormones, you know, the growth hormone and melatonin levels are starting to decline,
but other hormones are picking up.
So it is a really different stage that you also don't want to shortchange yourself on.
And I think that's the stage.
Many studies are showing that those are the times in sleep when the most crucial.
creativity can happen. That's when our dreams can incorporate and put together old and new things
together into a new way. And our schema are built during that time. So yeah, we can change our
minds best during those phases of sleep. Could you elaborate a little bit more on schema?
Yeah. I don't think anyone on this podcast has ever discussed schema. I'm a little bit familiar
with schema from my courses on psychology, but it's been a while. So maybe if you could just refresh
mine and everyone else's memory?
Well, it's still a concept.
Sure.
How do you define a scheme?
Right.
I think of schema as, like, we have a schema of Christmas, right?
We have all kinds of ideas that we sew together and call Christmas, a holiday season in the
northern hemisphere.
It's cold.
We have Santa Claus and reindeer and jingle bells and even things that are false that, but we
normally associate with Christmas presents, family gathering, when it is. All of this stuff
is sewn together into one, there's a thread linking them all, and we can just give ourselves
a list of words and none of them contain the word Christmas and then ask people later,
you know, give them another list of words and include the word Christmas and they'll say, oh yeah,
that word was there. Because in their minds, they brought up that word Christmas because it's
part of that whole schema. So that's what it's sort of a related, a lot of related concepts,
I guess. Can I think about sort of like on the desktop of my computer would scare some people,
but it's just a ton of folders. But each of the folder names mean something very clear and specific to
me. Right. And inside of those folders are collections of things that make sense in terms of how they're
batch. Is that kind of one way to think about? No, that's a great way to think of it. And when you're in
REM sleep in the later parts of the night and that transition to REM,
That's when your computer of your brain is opening folders and comparing documents,
seeing if there is there anything the same?
These two documents look very much the same, but there's a little bit of difference,
and it can link those conceptually so that that's probably one of the origins of creativity
is finding things that are related, maybe just linked a little bit,
and you can find that link and strengthen it if it, you know, makes your schema interesting and different.
Yeah. Very interesting. Many people, including myself, tend to wake up maybe once during the middle of the night to use the restroom. I've tried to drink less fluid before going to sleep. I've heard also that the impulse to urinate, forgive the topic, but a lot of people deal with this. So the impulse to urinate is also dictated by how quickly you drink fluid, not just the total volume. So I've switched to sipping fluids more slowly for my last beverage of the day, which seems to help. But the point here is that I think a lot of the
lot of people wake up once in the middle of the night, oftentimes you use the restroom, but
oftentimes just around 3 a.m. and might be up for a few minutes, hopefully not on their phone
or viewing any bright light, which can cause more wakefulness, but then go back to sleep.
Is there any known detriment to this middle of the night waking? Or should we consider it a
normal feature for some people's sleep architecture? Yeah, I think we shouldn't worry about it,
actually. I think, you know, sleep is really incredibly well homeostatically regulated. And so really
don't worry about how much you're sleeping, as long as you're not intentionally depriving yourself
of sleep by doing something really rewarding and exciting because even that is stressful to your
body and deprives you a lot of things we're talking about. So don't worry about it. It's absolutely
normal to wake up at least once in the middle of the night to go to the bathroom. And as long as
you can get back to sleep in a reasonable amount of time, you know, or even if it takes you an hour,
or don't worry about it.
As long as you have a lifestyle that allows you to then make up that sleep,
either the next morning or the next night,
or going to bed a little earlier.
So if I understand correctly,
there's a little bit of asymmetry to sleep that catching that first phase of sleep,
it's like you either get it or you don't,
and you have to get it by going to sleep essentially the same time each night,
maybe plus or minus 15 minutes or so.
But then if I wake up in the middle of the night and go back to sleep,
I can not catch up,
but I can gather all the sleep that I would have gotten had I just slept the whole way through the night.
Is that right?
Yeah, yeah.
Yeah.
And we don't know, actually, the answer to whether or not the sleep in the middle between that early sleep and the late sleep is, in fact, different for another reason.
And whether depriving yourself of sleep from, say, one to two 30 in the morning is bad in a different way.
We don't know.
Well, I suppose I am the experiment in that case because I do tend to wake up once per night.
And I've sort of come to recognize it as part of my normal sleep architecture.
I don't obsess over it.
I do notice that when I go back to sleep and especially toward morning that my sleep is
incredibly deep.
My dreams are incredibly vivid.
I don't always remember them.
But what is unique, perhaps, about the architecture of dreams and sleep in the, let's say,
the last third of the night or the second half of the night?
Right.
Yeah.
And the second half of the night, you have longer REM sleep periods.
and those are considered the deepest sleep,
even though slow wave sleep,
big slow wave is considered deep.
It is deep.
Yeah, they call slow wave sleep deep sleep
and REM sleep rapid eye in it,
but now you're telling me that REM sleep is actually the deeper sleep.
Okay, there needs to be a new nomenclature of sleep researchers.
You really shouldn't call it deep or not deep.
No, no, please.
The reason why you call slow wave sleep, deep sleep
is because it's difficult to arouse people out of that state.
And when you do arouse them out of that state,
they're most often confused and just want to go back into sleep and can go back pretty easily.
If you arouse someone out of REM sleep,
they're more likely to report something that was really kind of almost like wakefulness.
It was so vivid.
But in fact, if you give someone a non-threatening kind of stimulation,
like somebody dropping keys or a ping or something like that,
instead of waking that same volume will wake somewhat up out of non-rem sleep but out of REM sleep
and instead lengthen the amount of time or make it even more dense and rapid eye movements more
dense and often people will incorporate that sound into their dreams so the body and brain are
somehow conscious of the of the sound and I've heard also smells can even make it into our
dreams and in REM sleep but that we it doesn't arouse us it doesn't arouse us it doesn't arouse us
as often, yeah.
Interesting.
And maybe one of the reasons why REM sleep is deeper,
especially in adults and older people,
that deep slow wave sleep goes away.
So it's not as deep.
It's not as big.
The slow waves aren't as large,
which is probably problematic,
but we are not sure.
And so then REM sleep becomes the deepest stage.
Actually, in children,
it's kind of a toss-up
because it's really hard to wake them up
out of that deep slow-wave sleep.
And in fact,
fire alarms
don't wake them up, even really loud fire alarms out of that state of sleep.
So that's why they're trying to change fire alarms so that instead of something that the kids
don't associate with anything, like the whatever they don't associate.
It says their name or something else that may be less loud, but more salient to them.
And we'll wake them up.
I don't know, having carried sleeping children in from the car.
I don't know that I want children to start waking up from something.
because that's one of the best things when you get home and the kids are asleep in the backseat.
You can literally throw them over your shoulder gently, of course, and put them to sleep
and they are completely out.
Yeah, it's wonderful.
It is wonderful.
One of nature's gifts.
I'd like to take a quick break and acknowledge one of our sponsors, Athletic Greens.
Athletic Greens now called AG1 is a vitamin mineral probiotic drink that covers all of your
foundational and nutritional needs.
I've been taking Athletic Green since 2012, so I'm delighted that.
that they're sponsoring the podcast.
The reason I started taking Athletic Greens
and the reason I still take Athletic Greens once
or usually twice a day is that it gets to be
the probiotics that I need for gut health.
Our gut is very important.
It's populated by gut microbiota
that communicate with the brain, the immune system,
and basically all the biological systems of our body
to strongly impact our immediate and long-term health.
And those probiotics and athletic greens
are optimal and vital for microbiotic health.
In addition, athletic greens contains
a number of adaptogens, vitamins, and minerals
that make sure that all of my foundational,
nutritional needs are met, and it tastes great.
If you'd like to try Athletic Greens,
you can go to Athletic Greens.com slash Huberman,
and they'll give you five free travel packs
that make it really easy to mix up Athletic Greens
while you're on the road, in the car, on the plane, et cetera.
And they'll give you a year's supply of vitamin D3K2.
Again, that's athletic greens.com slash Huberman
to get the five free travel packs
and the year's supply of vitamin D3K2.
So this enhanced volume or proportion of rapid eye movement sleep in the second half of the night
relates to more elaborate dreams.
We are paralyzed during REM sleep, correct?
Yes, normally paralyzed and that's really good because that's the time when we're actively dreaming storyline dreams
and we could hurt ourselves.
We're actually really cut off from the outside world in terms of responding to, say,
table or a window or a door. And so different from sleepwalking, which is out of slow-way sleep,
and out of slow-a-sleep, that sleep-walking is a mixture between sleep and wakefulness. So you actually
will respond to the door. You can cook a full meal, drive your car while you're in deep
slow-wave sleep. It's scary because you never know what you're going to do. You don't have
voluntary, voluntary control over it. You don't have no conscious control over it. But you can actually
safely navigate some situations in sleepwalking and actually have a conversation, although it may not
make much sense when you're sleep talking. In REM sleep, you're not processing the outside world.
And instead, when you're acting out your dreams, you could be doing things like walking through a
plate glass window or falling off of, you know, down the stairs, things like that. So you really want
your muscles to be inactivated during REM sleep. Otherwise, you will act out those dreams and really
hurt yourself or your bed partner. What about sleep talking or talking in sleep? I don't know how many
relationships have been saved by sleep talking, but I'm guessing a few have been destroyed. And I'm guessing
that talking in sleep could have meaning or perhaps has no meaning just as dreams could have
meaning or no meaning as we recall them. Yeah. Do not take sleep talking seriously.
no matter what people say, it doesn't necessarily reflect truth.
So it's not like you're being more truthful when you're sleep talking.
You just saved a number of relationships.
I'm not directing this at anyone in particular, but I guarantee you just did.
Noted.
So as people start to approach morning or the time when they normally would wake up,
I've heard that it's important to, if possible, complete one of these 90-minute cycles,
to waking up. That is, if you set your alarm for halfway through one of these 90-minute
cycles that come late in the night of sleep, that it can lead to rather groggy patterns of waking.
So I'll just ask you directly, do you use an alarm clock?
I do not. Thankfully, I'm in a line of work that doesn't require me normally to do anything
at any particular time. I do it when I do it. Unless I have to catch a plane and then I always
set my alarm just in case.
Well, as a fellow academic, I can tell you there are plenty of punishing features about being an academic scientist that offset the fact that you don't have to use an alarm clock, but it is nice that you can often set your own schedule.
So would you recommend that if possible that people not use an alarm clock?
Yeah, absolutely.
If you can just listen to your body and wake up when you need to wake up, that would be great.
But one of the reasons why we have such a groginess, it's called sleep inertia when we wake up out of the wrong state, which is,
deep slow wave sleep is because I liken it to like a washing machine cycle.
This 90-minute cycle is like a washing machine cycle.
And the first part is to add water, right?
And then your clothes are soaking wet.
You don't want to open the washing machine and try and function,
put them on and wear them around while they're soaking wet and full of soap.
So you have to wait until the cycle is through before you can,
well, actually, let's put it in the dryer too,
before you want to wear them.
So yeah, you can function.
It just takes a little while for those clothes that brain to dry out so you can actually
function well.
But it's better to wait through the whole cycle is complete.
And so that's why you want to set that 90-minute alarm clock.
And again, that's around 90 minutes because the first stage of sleep, the first cycle of sleep
is actually a little longer.
more like 105, 110 minutes, but then the second ones and third ones, they get sort of shorter
and shorter as the night goes on. And in the last few cycles, you're just doing the N2 REM sleep cycle,
which takes less time. And if you wake up out of REM sleep, there's usually no problem
cognitively. You're good to go. Are you a fan of sleep trackers?
Sure. Yeah. Do you use one?
I have one on. I don't take, I don't, I don't, I don't, I don't, I don't, I don't,
live my life by them because they are the best ones right now are about 70% effective at
staging your sleep so 70% it's okay it's okay but um take it with a grain of salt is what i'm
saying yeah i've tried various ones and i compare the mattress based one to a actually wear it on
my ankle instead of my wrist but um and i do find it informative but a um a colleague of mine at
stanford ali crumb who works on mindset and belief effects um talked to me about a study they did where people
often will bias their sense of daytime wakefulness based on their sleep score more than their subjective
score. In other words, if they were told they got a poor night's sleep, even if they got a great
night's sleep and this was, of course, measured in the sleep lab. So they were able to compare. People
report feeling more groggy. And the opposite is also true that if it says 100% or 90% on your
sleep score, then people go, oh, I feel great even though they might not have slept well. So this speaks
to the, I don't want to say placebo effect, but the sort of belief effects that are woven in with a score.
That's right.
So it seems to me that combining subjective and objective data is probably best.
Yeah.
And I do believe that you should trust your own physiology and the way that your body is telling you to feel.
Because in fact, it used to be that people with insomnia weren't often not believed because you put them in a sleep lab and they look like they slept great.
And you wake them up in the morning.
They say, oh, I didn't sleep very well at all.
And that's because probably we just came out with a paper that shows.
that subcortical structures can be in a completely different sleep state than cortical structures,
which is what we measure in the sleep lab, what the cortex is doing.
So it might be that people who say, I did not sleep all night long, even though the cortex
is saying, oh, no, you had great sleep, was because they're monitoring their subcortical,
hypothalamus, hippocampus, thalamus, other structures that the sleep lab just can't access,
unless you have depth electrodes, which nobody really wants.
Right, because that requires holes in the skull.
Holes in the skull.
Holes in the skull.
And wires.
Yeah.
Wow.
So does that mean that the last 50 plus years of sleep science, it's potentially flawed in
some way because they're only recording from, I guess this would be, the analogy would be,
it's like recording from the surface of the ocean as opposed to the depth of the ocean.
Right.
And trying to ascertain the life moving down deep in the depth.
Brace yourselves, colleagues at Stanford.
sleep lab and elsewhere. But please just tell us because I think scientists want to know the truth.
Yeah. I mean, it's not for nothing that you want to know what the cortex is doing. I mean,
the cortex is really important for a lot of things, but it doesn't necessarily tell you what
a lot of other really important parts of the brain are doing in terms of sleep. But there's hope
because, in fact, it would be great. I think that's possible from the paper if you look at it.
it's in PNAS this year, that you could detect subtle changes in the cortical EEG that might be able
to tell you what the subcortical structures are doing.
Things like the absolute power in that sleep spindle band, that sigma band would change
if the hippocampus is in REM sleep and the cortex is in that sleep spindle state and vice
So there is some hope that we can gain from people with depth electrodes or animals with
depth electrodes that we could backwards machine learn what the cortex might be able to tell
us about subcortical structures from the cortical eG.
So interesting.
This is going to be a stimulus.
Yes, stay tuned.
It's going to be a stimulus for development of new technology, which is always going to assist
in scientific discovery.
There's one more thing I wanted to ask about the architecture of the night's sleep in terms of early part of the night.
Earlier, you mentioned the washout of debris and the so-called glymphatic system, I think, is what you're referring to.
Could you tell us a little bit more about the washout that occurs in the brain during sleep?
What that is and what roles it's thought to serve?
And perhaps if there are any ways to ensure that it happens or to ensure that it doesn't happen, and obviously we want this to happen.
Yeah, yeah. All right, great question. We talked about the circadian clock and how certain things happen at certain times. Well, one of the things that happens when we're awake and talking to each other is that there's a lot of plasticity. There's something that I'm learning from you today and you're learning from me. And that changes our synapses and it changes the way our proteins are going to be folded and changed during sleep. It unfolds. This process actually,
uses a lot of ATP, the power structure, the fuel of the brain. And it unfolds also proteins
while we're doing this while we're using them. And so during that first part of the night,
when we first while asleep in the first 20 minutes or so, we're building that adenosine
back into ATP. And that's probably why power naps are called power knots, because we're actually
rebuilding the power. And then we're also cleaning out through the deep slow waves of
slow-wave sleep, we're cleaning out all those misfolded proteins, unfolded proteins,
and other things that get broken down and, you know, need to be rebuilt when we're asleep
because of its use during wakefulness. So I liken that to, you know, having a big party during
wakefulness and you need all those partygoers to leave in order to do the cleanup.
And so what I think the mechanism is, and this is still something to be tested, is actually
slow waves themselves, which is bad news for us as we get older and those slow waves get smaller
and slowly sleep goes away.
So what happens when a neuron is firing is that it expands.
The membrane expands a little bit.
It becomes more translucent.
That's how we know.
One of the ways we know that neurons expand when they fire.
And so every action potential, the membrane expands a little bit as sodium brings water into the cell.
And then when they're silent, they contract.
And so during slow waves, the cool thing is that the reason why you can measure them is that all the neurons at the same time,
not all of them, but a good portion of them, are firing at the same time and silent at the same time.
And so you think about that as contracting and expanding all at the same time.
It's kind of like a bilge pump of the brain.
can pump out. Glea are also really important for this in terms of cleaning up debris and transferring
it to where it needs to go. So I think of it actually as a bilge pump cleaning out our brain.
Interesting. I've heard about the glymphatic system and lymphatic washout. I've never thought
about the mechanical aspects of it before. I always thought that for some reason that now it's
obvious to me there had to be something mechanical, but only now that you've educated.
me about this. I thought that for some reason the cerebral spinal fluid just starts washing through,
but here you're talking about literally an expansion and a contraction of the neurons in unison
and pushing the fluid through cleaning out any misfolded proteins or debris that might occur
on the basis of these metabolic pathways. And the consequence of that is to, to what,
to leave the brain in a state of more pristine action for the next day? Is that right?
you think of it again like a party and if you don't clean up after that party you try and hold another
one the next day it's going to get more clogged you know it's people have a harder time moving around
and enjoying themselves and if that builds up day after day you know it's going to be cognition
that would be the party goers moving around um becomes hard yeah and so this um build's pump
that you describe is associated with the big slow waves of of deep well
of slow wave sleep.
Yeah.
So this is going to occur more or less in the first third of the night.
Is that right?
That's right.
And are there things that inhibit this process
and are there things that facilitate this process?
Yeah.
So, well, one thing to inhibit is not to get it.
Right.
And here too.
Sorry to interrupt.
And is this similar to the case with growth hormone
where if you go to sleep later than you would normally,
you miss the washout?
Yeah. It's not, you don't delay it. You miss the washout. That's right. That's right. So if you go to
sleep at one or two in the morning, your sleep is still going to be dominated by N2 and REM sleep,
not by slow wave sleep. So you need to, you need to get that first bit of sleep.
Would a caveat be if somebody normally goes to sleep at one or two a.m and wakes up at 10 a.m.
Yeah. If that's their normal sleep cycle. Yeah. That should be okay. It should be okay.
you would probably want to do, somebody would want to do a sleep study with people who do that normally
and see if also the melatonin releases later and the corticosterone rise that happens normally in the
morning also happens later. So if everything shifted, good. Okay. Yeah, there are a few studies I've
come across that really do argue for the fact that waking up circa sunrise, that doesn't mean at
sunrise, but within an hour or two, maybe three hours of sunrise and going to sleep within
four hours after sunset or so is actually better for the health of all human beings than is
being a night owl.
And the night owl, there's almost like a night owl posse out there, especially on social
media.
They get very upset when you say that you should see morning sunlight that after 10 a.m., you kind
of miss the boat.
They get very upset because I think there are about 20 or 30.
percent of people perhaps who really feel like they function better, staying up late and waking
up late.
And they function much less well waking up early and going to bed early.
But the data on health metrics suggests that sorry night owls, that they are wrong.
Yeah.
Sorry me because I'm a night owl.
Oh, boy.
Okay.
Well, then I'm apologizing directly.
And here I'm not a really early morning person.
I'm kind of more typical if I wake up naturally around 6.30, somewhere between 630 and 7.30 a.m.
go to sleep somewhere between 10 and 11 p.m.
These are averages.
But I do notice that when I force myself to get up a little earlier and go to sleep a little
earlier, that my mood and alertness and just overall productivity is much higher.
And there could be other variables there too.
You're absolutely right.
I'm a night owl.
I love staying up late at night, doing, you know, writing grants, writing papers, watching
movies, whatever it is.
I love it.
But I like you and like every human being on earth, do better if I go to bed earlier and wake up earlier.
So one good thing for night owls is to have a child because they will wake you up.
Their circadian rhythms are so strong.
They will wake up.
And even if you deprive them of sleep in the first half of the night, they will still wake up like clockwork because their circadian rhythms are so strong at 6 a.m.
And so what you've, you haven't done anything good for your kid.
You haven't moved their cycle to later and be more in line with yours.
In fact, you've just sleep deprived them and made them miss a window and made them cranky the next day and made your life more miserable.
So go to bed soon after your kids go to bed and wake up with them.
That's the way to do it.
Great.
The child alarm clock.
Another reason I have children.
Yes.
I got a dog, a puppy.
And then that became a dog specifically, well, for many reasons.
But one reason was I wanted to be one of those early morning, you know, 5.30 a.m. every morning.
But I ended up getting a bulldog that would literally sleep 16 hours if he could.
A nuclear bomb could go off and he wouldn't wake up.
But what I started to learn was that bulldogs actually have sleep apnea.
As far as I know, they're the only species that has a genetically, they're essentially an inbred sleep defect.
And so I actually don't encourage people to get bulldogs because it's kind of a cruel breed.
they suffer a lot in that body that they're born into.
Anyway, a dog can accomplish some of this,
but get the breed of dog that is going to wake up early.
So in other words, don't get a bulldog or a mastiff.
Well, you know, interestingly, all predatory animals like dogs and cats and lions and us,
well, more dogs, cats and lions than us wills can sleep, you know, 16 hours a day.
Ferrets are predatory.
I had a pet ferret.
Yeah.
And sadly, I also used to work on ferrets, publish a number of papers.
Delightful animals.
Yeah.
And great because you can study development.
It's really cool because they're born very altricial like we are with brains that are not very well developed.
And so you can see what happens through development and how important these different phases of development really are.
But yes, yeah, maybe we're not as predator as much predators as we think because in fact our sleep is somewhere.
between the prey and the predators in terms of the amount of sleep that we usually need a night.
But those predators can sleep 16 hours napping all day long, and they're more crepuscular,
perhaps, like their prey are more...
So dawn and dusk active?
Yeah, dawn and dusk active.
Yeah.
But anyway, yes, children and dogs, actually, if there was a poll done by the National Sleep Foundation
to see what the number one thing is that wakes people up at night.
And number two is going to the bathroom.
Number three is children because, you know, when your children are young,
but that only lasts a few years that they'll wake you up when they're babies.
But the number one thing is pets, and pets needing to go out or cats wanting to curl up with you
or whatever it is, pets needs will wake you up more in the middle of the night than anything else.
Another reason to not get a nocturnal pet.
People who get hamsters pretty quickly realize that they are nocturnal and they want to run on their wheel and around.
Yeah, you got to put them in the living room away from where you sleep.
I vote fish tank, folks.
Freshwater fish tank.
There are all sorts of reasons to not get a saltwater tank.
Freshwater fish tank or a child.
I appreciate that vote.
And I appreciate you mentioning ferrets.
And by the way, folks, they are carnivores.
They are not rodents.
And they have very elaborate brain structures.
They're very smart in the same family.
as the honey badgers and the other mustelids.
Anyway, I shouldn't geek out too much on the mustelids or else I'll take the remainder of all
our time.
I'd love for you to tell us about REM sleep and the sleep later in the night as it relates
to dreams and emotionality.
And this is probably the appropriate time for you to introduce us to this incredible
structure in the brain, which is the locust serulius, a difficult structure to spell,
but a beautifully named structure.
I find locust serulis to be just fascinating,
and I know a small fraction of what it does,
and I'm hoping you're going to educate me
and our audience about more about what it does,
and hopefully tell us a little bit about its relationship
to epinephrine, aka adrenaline.
Yeah, I'm so glad you brought this up
because I can totally geek out on the locust surilus.
Please do.
Locus meaning spot or place,
and surilus meaning blue,
so you could just call it the blue spot.
That's the easiest.
Every animal with a brain has a blue spot.
And I mean every animal with a brain
because, of course, there are animals with nervous systems
that are not centralized like jellyfish.
But anyway, we're digressing there.
So the locusyrolous is filled with neurons
that have in them noropenephrine,
which is the brain's version of epinephrine
or adrenaline.
It's also called noradrenaline.
And what it does is it, just like adrenaline and the rest of our bodies, it helps prime us to respond to our environment.
So when locus rurulus neurons fire and fire in a burst, we can switch our attention.
And they will fire in a burst if, for example, a loud noise happens in the middle of your concentrating on something.
So it helps, it fires, and it helps you switch your attention to that thing and then learn quickly from it.
So it's really important in a stress response.
It helps us do a quick one-trial learning.
And then a tonic activity during the day when you're just, you know, doing normal, going about your normal concentration kind of activities is really good for sustained attention.
It works with the colonergic system of our basal forebrain, which is really important for learning and memory also to help us learn about things and put things together.
but just tonic levels are signature of wakefulness and alertness.
So too much is panic with the locusurellus activity.
A burst is switching attention, and then tonic levels are sustained constant attention.
And then when we go to sleep, the locuserilus slows and goes from about, on average,
two hertz to about one hertz, one cycle per second.
tonically. And then when we go into REM sleep, it's the only time when it shuts off completely. And
it appears that that complete silence is really, really important for a number of things. And the
main thing that I think it's important for is the ability to erase and break down synapses that are
no longer working for us. So they encode things that are false now, or they are encoding things that
we learned in the novelty encoding pathway of our brain that have now been consolidated to other
pathways. And so we need to now erase them from the novelty encoding pathway. And that is really,
really important for being able to continue to learn things all of our lives. So like erasing that RAM
or that, I don't know, what do you call those disks that you stick into computers?
No, hard drive. No, thumb drives. Yeah. Erasing your thumb drives. So you're raising your thumb drives.
So that thumb drive is what you carry around all day long.
And then during sleep, you write that thumb drive to the cortex, to the long-term memory structures,
and you need to refresh that thumb drive.
And that's what happens during REM sleep when the locus surrealus is off.
Because whenever it's on and neurodrenaline is there, it helps us to put things together.
It helps us to learn and strengthen synapses.
But it does not allow us to actually weaken synapses that are also a really important part for important part of lifelong learning.
Yeah, there's so much more I could say about that.
Yeah, Locus ceruleus sounds fascinating.
So it's connected to the basal four brain colonergic system.
The neurons in locuserulius, if I'm not mistaken, release noraphenephrin, perhaps epinephrine as well?
Well, no, the brain's version of epinephrine is noraphenephyran.
The other thing it also, the precursor to norapenephyne is dopamine.
And so the source of dopamine in the hippocampus seems to be the locusyros, and it's still a mystery, is under what conditions the locus reels also releases dopamine, but it's really important when we're learning something new to also release dopamine or to at least activate the dopaminergic receptors in our hippocampus.
So, yeah, so dopamine, noraphenaphyne, and then there's also galanin, which is important for releasing when we're stressed, and it has,
helps also without rapid learning. It works in concert with noraphenephrin and in doing what it
needs to do to strengthen synapses so that we learn really quickly. I love that there are multiple
molecules involved because that signals us to a principle, which is that even if people can't
remember all the names, that rarely in biology is something handled by just one molecular pathway,
that redundancy is the rule because signaling attention to specific events is so important.
So that I'm going to use that as a just so story.
I always say, you know, I wasn't consulted at the design phase, but it makes sense to me
as to why redundancy would exist in the system.
Absolutely.
And in fact, when we form hypotheses about the brain, we're always wrong.
And the reason why we're always wrong is because it's more complicated than we like to think.
And because in our brains when we're forming hypotheses, it's we fail to account.
for all of the factors that are involved, the glia, the neuropeptides, the neurotransmitters,
the physical structure of synapses. And so when I was going through grad school 35 years ago,
the dogma was that every neuron contains one neurotransmitter and releases one neurotransmitter.
And you had excitatory neurotransmitters and inhibitory neurotransmitters and neuromodulatory
neurotransmitters, but that's as complicated as God. And then we started talking about
neuropeptides and people said, oh no, please don't, don't complicate it. And then we started
talking about how neurons contain both neuropeptides and neurotransmitters and maybe more than
one neurotransmit. And maybe even hormones too. And hormones and oh Lord, you know, it's just so
complicated. But I've got to admit that's why it works, right? And every time the brain teaches
us something new about itself that we didn't hypothesize, we say, oh, of course, that wouldn't
work if the way I hypothesized it with it. You know, we actually need redundancy. We need all these
systems to work together.
It's daunting sometimes, but it also ensures many, many careers in science and neuroscience
in particular.
So note that aspiring scientists, there's plenty of room for discovery.
Do you want me to talk about norepinephrine and emotion?
Yes.
Well, what I'd love for you to tell us about is, you know, what role this lack of norepinephrine
release during rapid eye movement sleep?
is thought to achieve.
And maybe you could also review some of your work describing conditions under which
norapaphenephrin invades.
Yeah.
Invades sleep.
Rapid eye movement, sleep and other patterns of sleep and how that can be detrimental.
Yeah.
So a lot of this is hypothetical, but based on a lot of good evidence that we're sewing together
into a schema from which these hypotheses come.
So a model schema from which the hypotheses come.
But one thing that happens to people with post-traumatic stress disorder is,
that there is a lot of evidence that the locusyrilis doesn't stop firing in REM sleep.
So whereas there levels of noraphenephrine might be similar to people without PTSD during
the day and even during the first part of the night, during the wee hours of the morning,
and when you measure noraphenephine levels from metabolites in the blood or the cerebral spinal
fluid, you see that people with PTSD, it's during the wee hours of the morning when you have
the most REM sleep that they have, their neuropenephyran levels differentiate most from those
that don't have PTSD. And so that's evidence that the locus serilis is not shutting down during
REM sleep like it should. Other evidence is heart rate variability. When our locus aerolus is firing,
our heart rates are generally a little higher and they don't vary as much as they do when
the locustyurelis is not firing. So during slow-wave sleep, normally have this big juicy
variability in heart rate with every breath in and breath out because our noradenergic levels,
our noropenephrine levels are lower during REM sleep that goes away entirely and our heart rate
is is dominated by parasympathetic rather than sympathetic activity and also what our brain is
driving, you know, what are dreaming about, for example, if we're dreaming we're running, our heart
rates will go up. But noraphenephine levels still should be low or off.
So people with PTSD that noregenergics, we're studying these in rats too.
Is it true that our locustralists doesn't shut off when we have post-traumatic stress disorder?
And the preliminary evidence is, yes, it's true that it doesn't shut off.
So what that would do is noropenephrine would act at synapses to prevent that weakening
that you really need, for example, of novelty encoding structures.
and it keeps memories in that novelty encoding structure even once it's consolidated to the rest of the brain.
So in the hippocampus, which is important for remembering things throughout our lives and it's that thumb drive,
we need it to be erased so that we can learn new things once it's been consolidated to the hard drive of our cortex.
And so if we're not able to do that, we fill up.
up that REM really quickly or that thumb dive really quickly and we're not able to learn new
things. So for example, after a trauma, I talked about the Locus Rillus responding in stressful situations.
That's great. It's very adaptive. But then you need it to stop. Once you've learned what you
need to learn from it and you want to go to sleep, you need the locus rilus to calm down.
And during REM sleep, you want it to stop because then when you've consolidated that traumatic
memory to the cortex, you need to erase it from the novelty encoding structures. For example,
in the hippocampus so that then when you're in the context of safety you can learn those new things,
those new contexts and stop responding to those same stimuli as though you're in that original
situation. So if you're not able to erase that thumb drive, you will always feel like that
trauma happened that same day, like earlier that same day, and respond as you would to an early
a recent trauma, which is with beating heart and all of that. So even memories that are years past,
if you're never able to downscale that novelty encoding structure and purges it from that traumatic
memory, it will stay fresh and new and then become maladaptive.
What approaches are you aware of that can turn down the output of Locus Cirulius during these
phases of sleep and for that matter what things can cause ramping up of locus surrelius during this phase
of sleep we've had a couple podcast episodes solo episodes and with guests talking about trauma we had
dr paul conti who's a stanford trained harvard trained um psychiatrist who talked a lot about trauma
wrote an excellent book on trauma. And certainly sleep was emphasized as a key thing, like get enough
sleep. But here you're saying even if somebody with trauma gets enough sleep, if Locusurulius is
hyperactive during sleep, those traumas are going to persist. And most of the trauma treatments that
I'm aware of are everything ranging from cognitive behavioral therapy, talk therapy, drug
therapy, EMDR, hypnosis. Nowadays, there's a lot of interest and attention on clinical studies
on exploring psychedelics, high-dose psilocybin and MDMA.
So it's a vast landscape, none of which, as far as I know, is really focused on sleep
specifically.
No, they're not.
And they should be because actually psychedelics is a sleep-like state.
And it's a REM sleep-like state, although, of course, there are some major differences.
So, yeah, so much to talk about here.
So antidepressants are often noradenergic or serotonergic reuptake in.
inhibitors. So they leave neuropinephrine actually out there in the synapses. And what that does is it
inhibits REM sleep. And if you're able to get REM sleep, it would probably be REM sleep with some
neurodienergic activity. So actually, I think, anyway, I'm not a physician, that antidepressants are
counterindicated. You don't want to take them if you've experienced a trauma and you're experiencing
PTSD, because if anything, it's going to make it worse or at least prevent the type of adaptive REM sleep
that you really need in order to resolve those emotions and move on.
Is that statement specific to antidepressants that tickle the noradrenergic pathway?
So the one that comes to mind is I can never pronounce it,
Brupropyrion, which is what I think brand name is Welbutrin.
It's a dopaminergic and noradrenergic agonist.
That's the net effect, as opposed to the pro-zaxyl loft variety, which are SSRIs.
Yes, yes.
but SSRIs themselves also are problematic because we didn't talk about it yet, but the dorsal rafé nucleus,
which produces serotonin, which the specific serotonin's specific serotonin reuptake inhibitors block from
being reuptaken leaves too much serotonin out there. And what serotonin also is another
neurotrenergic, I'm sorry, another neurotransmitter that's downregulated during REM sleep. That's
specifically off during REM sleep.
And what serotonin does is it weights all of our cognition to being able to recognize novelty
again.
So it sort of weights our brain away from a sense of familiarity and toward novelty.
And it might be one reason why it's an effective antidepressant because it makes the world
feel fresh and new again, right?
but you when you have a too much you're holding a novel traumatic memory in your novelty
encoding structure too strongly already you don't want to again wait things toward novelty
you need that absence of serotonin also to help you get that sense of familiarity and to
start erasing the novelty encoding structures so you need both to be absent it's really
interesting. We hear a lot about serotonin and it's not often discussed in terms of its features
related to novelty enough, I think. And what you just described, excuse me to something that
Dr. Paul Conte and others have said in terms of trauma. And here I'm paraphrasing, so my apologies
to them for not getting this exactly right, that an effective treatment for trauma does not erase
the traumatic memory, but it causes a transition of what once was disturbing and invasive.
and maladaptive to eventually just become kind of a boring old story that has kind of a fuzzy
texture to it as opposed to this kind of sharp high friction texture that invades our thinking
and obviously our sleeping states as well. So again, and I appreciate the disclaimer, the caveats around
not being a clinician, et cetera, but I do think that there's a lot of interest now in whether
or not antidepressants are effective for trauma or not.
I think these aspects of neuromodulation as they relate to, let's call it erasing traumas
or changing the emotional load of traumas during sleep is something important to take note.
We also have a lot of clinicians that listen to this podcast, so they should also take note.
Please.
So if I want to reduce the amount of norapinephrine, release from locust serulius during rapid eye
movement sleep to eliminate the troubling or maybe even traumatic memories and allow late stages
of sleep each night to have their maximum positive effect.
Is there anything that I can do besides avoiding, avoiding traumas, avoiding serotonergic
or noradrenergic compounds?
Well, I would also avoid anything just prior to going to sleep that might excite
those systems.
So a lot of novelty, a lot of, you know, there's a lot of, you know, there's a lot of, you know, there's
exciting, stress-inducing video games, try and enter sleep with as much calm as you can.
So maybe deep breathing exercises.
That's a beautiful way to calm your sympathetic fight or flight system, is deep breathing.
And we haven't been able to test this with rats because we can't ask them to do a deep breathing
exercise.
There might be a way we can do that, but I haven't found out or figured it out yet.
But if there's a way you can make your sympathetic system, nervous system, calm down before you go to sleep,
might free for you meditation or deep breathing exercises might be for some, a warm bath or a comforting book,
nothing too exciting, but also nothing too boring, perhaps.
Just something right in the middle which makes you feel happy and calm is what you should do.
And if you instead go to sleep while you're anxious or you're hyped up, then your sleep could become
maladaptive.
Another thing that happens in rats that we have yet to know if it happens in women is that
female rats have three phases of their estrus cycle that their locust realist doesn't seem to calm
down during REM sleep as much.
And we don't know why, but during the high estrogen phases of their estrus cycle, they
cycle, the locustrillas shuts down just like it does in male rats, but in the other three
phases, it doesn't.
So one thing that might work, and in fact, there are a few studies that show it, it could
work really well, is giving women after a trauma event something that contains estrogen,
because estrogen somehow is protective against PTSD, and they know that through a retrospective
studies where they gave women an emergency room, either a pill with estrogen or without,
and those that had the pill with estrogen in it were much less likely to get PTSD from that
trauma as measured a year later than those that had the pill without.
So there's some really good studies by Bronwyn Graham.
She's out of Australia to really hone in on how much estrogen do you need.
And also testosterone, just so you know, gets converted to estrogen in the brain.
testosterone also can be protective because it gets converted to estrogen. But there's something about
estrogen that's really helpful and protective about that from the high locusyrilis firing.
And this is, again, preliminary data that we don't have full, we don't have all the answers yet.
And we are looking into it actively right now, but it's really important. The other thing about
women is that we are two to four times more susceptible to anxiety related mental health disorders,
including post-traumatic stress disorder.
So if we could figure out what's happening to the locus
furlists during sleep in women,
and then figure out a way to normalize that
so the locus realist is silent when it needs to be silent,
I think we could go a long way in helping women be more resilient
to stress-related disorders.
What are some other sex differences as they relate to sleep?
Yeah.
Yeah, that's a really good question.
There have been very few studies, unfortunately, of women in sleep, women, an estrus cycle,
or menstrual cycle in sleep.
But what we have found, which actually largely replicated the study in 1960, is that
women, or females, rather, at high estrogen, high hormonal phases of their estrus
cycle or menstrual cycle, sleep a lot less, but that's.
sleep is more efficient. So that sleep is more dense in those sleep spindles, which I haven't
gone into what they might do, except this connection between the hippocampus and cortex. But those
sleep spindles are more dense and more coherent across the brain areas. The theta cycle, which is
5 to 10 hertz in the hippocampus, important for one year learning and also important during
REM sleep is also bigger and juicier during the high hormonal phases. So even though there's less sleep,
but it's more efficient and better.
So all of that efficiency seems to be reduced in those other hormonal phases.
So even though you might sleep a little more,
you might need more sleep, in fact,
in order to accomplish the same thing that you can get with that short,
very efficient sleep of high hormonal phases.
Very interesting.
I think there's a lot of,
a growing trend, at least among NIH-funded grants, to require that, as they refer to it, in
the grants, biological sex as a variable.
And here we're talking about sex, the verb, although I'm sure there's studies about
that too, but biological sex is a variable because there is a dearth of studies exploring
sex differences in most everything.
There are all sorts of reasons for that, but more importantly, fortunately, the trend is shifting.
Yeah. And even when you study males versus females, a lot of people just include females in their studies, but then don't track the estro cycle or menstrual cycle.
And hormones have huge effects on our behavior. I mean, just think about when you said sex, you know, before our hormones come in, we're not interested in it. And suddenly, you know, that's kind of a main driver of our behaviors.
There's hormones can definitely change who we are and what we do.
So we should be studying hormones, not just sex.
I always say that puberty is perhaps the most massive transformation and rate of aging
that any of us go through in a short amount of time.
And their cognition changes, their worldview changes.
And that's largely hormonal driven.
And obviously neural architectures change too.
I'm very happy that you mentioned I'm trying to get into calmer states prior to sleep
and some ways to do that.
I'm a big fan and I've talked a lot before on this podcast about things like yoga nidra,
which is a non-movement-based practice, sometimes called non-sleep depressed,
where people actually take some time each day to practice how to go into a more
parasympathetic, aka relaxed state deliberately.
Because it's a bit of a skill.
Yeah.
Yeah.
And there's some good data really, mostly out of a laboratory in Scandinavia,
showing huge increases in nigrostriatal dopamine when people go basically engage in.
a practice of deliberate non-movement and that the brain actually enters states of a very shallow
sleep. So sort of napish, but the idea is to actually stay awake but motionless. And it does seem
to restore a certain number of features of neurochemistry. But perhaps more importantly, it teaches
people to relax, which is something that most people are not very good at. But in any event,
and people who listen to this podcast have heard me say this over and over again. So I sound like a
broken record. But this practice, as a zero-cost practice that doesn't require any pharmacology,
does seem to really enhance people's ability to fall asleep more quickly and to fall back
asleep if they wake up in the middle of the night. So in any event, another plug for NSDR,
Yoganidra. Well, I just also want to add to that. That's one of the reasons why insomnia is so insidious
is because when people feel like they haven't gotten enough sleep and they aren't getting enough
sleep and they become anxious about getting enough sleep and then you're anxious before
going to sleep, like I'm not going to fall asleep. It's going to be 45 minutes in. And then
that's a positive feedback loop. So you need to break that loop. Say, okay, my body's going to get as
much sleep as it needs. I needn't worry about it. And then practice this relaxation to say,
hey, it's all okay. It's going to be all right. And then concentrate on things that relax you,
whether it's concentrating or not concentrating, whatever it is. You mentioned yoga
NEDRA, and that reminded me of transcendental meditation, which is something that also hasn't been
studied well, are largely because we can't ask non-human animals to do it. And so we don't know
what's happening with our neurochemistry and our brain activity in a deep and meaningful way.
But one thing that has been shown in those that can do it really well is that that theta
activity that I said happens when you're learning something or what?
when you're in REM sleep, it's well established and increases during the transcendental meditation.
So it might be that some states of meditation could in some ways replace or mimic some functions of,
for example, REM sleep.
But again, we don't know if all the neurochemistry is right to do, for example, the thing that
I was talking about, which is erasing the novelty encoding structures of the brain.
That needs an absence of neuropenetphrine and serotonin, which we don't know if that goes away with transcendental meditation.
We just don't know the answer to that yet.
Yeah, the studies on Yoganidra and sleep replacement are kind of interesting.
It does seem to be the case that nothing can really replace sleep except sleep,
but that if one is sleep deprived or is having trouble falling back asleep, that these things like,
and I hear it's, I acknowledge this is essentially like Yogan.
but we now call it non-sleep deep breast or n sDR because oftentimes for names like yoga needra act as a
kind of a barrier for what would otherwise be people willing to try a practice it sounds mystical
and yoga it sounds like you have to go to eslyn by the way esselin's a beautiful place but it sounds like
you have to go there or live in the west coast to to believe in this stuff but it's simply not the
case these are practices that that are really just self-directed relaxation as a practice that
allows people to get better and better at directing their brain states towards more relaxation.
And most people have an asymmetry. Like, for instance, most people can force themselves to stay up
later, but they have a hard time going to sleep earlier. And that just speaks to the asymmetry
that's probably adaptive and survival base that we can ramp ourselves up far more easily than we
can tend to calm ourselves down. Yeah, yeah. And actually, you know, to appeal to other Christians
like me, prayer can be a wonderful way to calm.
yourself down because through prayer you're giving your cares to God and saying, you know,
and then you are relaxed, more relaxed. And I just want to say that because the same reason that
yoga might put some people off, it might put some people off to talk about prayer, but it's the
same process of being able to relax. And yeah. And get outside our own experience a little bit.
experience, yeah, back out, get a worldview that might actually also help us to relax.
Well, you might be surprised at how many clinicians and scientists who've come on this podcast
have mentioned things like prayer from various perspectives, Christianity, Judaism, Muslim
traditions and others that as a parallel to all of these things.
And I think what it speaks to is the fact that ultimately the biological architectures
that we're all contending with are going to be identical, right?
And so different ways to tap into them.
and ones that are congruent with people's beliefs, I think, are great.
Yeah, because anything non-congruent with your beliefs are also stressful.
Right, and feels forced.
And that's why, you know, this idea of calling it non-sleep deep rest in addition to Yoga Nidra
was not to detract from the naming or the history around Yoganidra.
But I was finding that it was a barrier.
You know, likewise, Yoganidra tends to include things like intentions, whereas NSDR scripts.
And by the way, we will provide links to some NSDR and Yoganidra scripts.
but NSDR has no intentions.
It's simply a body scan deep relaxation base.
So it's sort of the scientific version of all of this stuff.
And actually we study it in the laboratory and some of the brain states that people go into.
But that's a discussion for another time.
This is hard.
My mother used to tell me when I said, whatever, we complain.
I can't go to sleep.
She'd say, well, you know, start with your toes and relax.
So you would clench your muscles around your toes and relax them and do that all the way from your toes all the way to your head.
And I don't know where she got this.
It might have been her own common sense,
or she might have gotten it from this NPR show.
It's called The Mind Can Keep You Well.
She used to listen to.
But that's another intentional relaxation
that focuses on the body rather than on your own mental processes.
I do a little bit of work with the military,
and there's a method within certain communities
of special operations in the U.S. military
where if they can't sleep or they're having challenges sleeping,
they will deliberately try and relax their facial muscles in particular, like sort of drape
the facial muscles and use long or exhale emphasized breathing does seem to increase the
probability of transitioning back into sleep.
And those are hallmarks of yoga, nidra, non-sleep deep rest, body scans.
And so I think all of these things converge on a common theme.
You know, as neurobiologists, we can say all of the things that we are describing certainly
move the needle away from locus serulius activation. I mean, we haven't done the experiment to
really look at that, but it seems all these things are counter to noradrenaline release.
Right. Another one is yawning. Yawning in itself is that kind of sort of tensing of all the
muscles in your face and then relaxing them. So it might be why we yawn. We don't know why we
yawn yet, but it might also have, it would be really great. Actually, animals yawn too, you know.
My bulldog was a perpetual. If he wasn't sleeping, he was.
yawning. And it would be interesting to see what yawning does to the locus surilus. Does that also
come and switch the locus serilus activity? Because it's interesting that facial nerve, like
trigeminal nerve, you know, through the vagus connects indirectly to the locus serilis and has a
powerful effect on that. Interesting. A common, I think, friend of ours and direct colleague of
yours, Jack Feldman was a guest on this podcast telling us about all the amazing structures. He and
others have discovered in the in respiration and breathing. Sounds like we have a collaboration brewing
that the three of us should should definitely carry out. I'd love for you to share with us a little bit
more about the spindles that have come up a few times. And I don't know if it's relevant to this.
So if it's not, let's separate it out. But I'd love for you to tell us a little bit about the
role of sleep in problem solving and creativity. And if spindles are involved, then I'll consider
myself lucky for batching them in the same question. And if they're not involved, simply feel free
to separate you know. I think they could be involved. And the reason why I think there could be
involved, because we now know a lot more about spindles. First of all, the first thing that we knew,
first of all, we ignored them. Then we thought they had something to do with keeping us asleep,
and that was their function. It was when an external stimulus came, they would keep us asleep
because they would arise. But now we know that the density of our sleep spindles, the number that
we produce per minute, is well correlated with our intelligence in the first place, and that no matter
what your intelligence is, and no matter what your sleep spindle density is, if you learn something
during the day and increase your sleep spindle density, it's really almost perfectly correlated
with our ability to consolidate that information and incorporate it into the schema that we already
have in our brain. So if you try and learn something new, even if your sleep spindle density at baseline,
it's great. If you don't increase your sleep spindle that night, you're not going to use sleep
to really incorporate it.
Interestingly, sleep spindles are poor in those with schizophrenia.
It's one of the characteristic signatures of sleep is that sleep spindles are very few and far between,
which might mean that people with schizophrenia might not be able to incorporate new information
into already existing schema.
And instead, it sort of flaps in the breeze out there and can be accessed erroneously at times
when you don't want it to be involved.
I digress. So sleep spindles and creativity. So one of the things we now know through some great studies by Julie Seep and Anita Luthy is that sleep spindles are accompanied by an incredible plasticity out in the distal dendrites, the listening branches of our neurons that listen to other cortical areas.
So there are proximal dendrites in our neurons that listen to the external world and are conducted through the thalamus.
and then there are distal dendrites which listen to an internal kind of, you know,
conversation that's happening in our brains.
It's kind of, you know, our internal state, really.
And during sleep spindles, that's when those distal dendrites are able to best learn from other
cortical areas and from the hippocampus.
It is during sleep spindles that the hippocampus and the cortex are best connected
and when that incredible plasticity can happen.
When I talk about schema, that's a cortical.
cortical thing. That's when, you know, the image of Santa Claus and presence, you know, comes together.
It's not through some external thing. Once we learn those things together, it's our cortex that
encodes that and brings those images back up together. And that's during sleep spindles when that's
happening, when that there's big surges of calcium into those distal dendrites and where plasticity
happens in just huge amounts. During that sleep spindle stage of sleep,
which is N2 stage.
There's also another excitatory event
that comes all the way from the brainstem
and projects everywhere in our cortex,
which is called PGO waves,
P for ponds, G for geniculate nucleus of the thalamus,
which is where they're first discovered,
an O for occipital area,
which is a visual area,
which is, again, where they're first discovered.
But in fact, it's now been shown that PGO waves,
which we should generalize to Phthalmases,
because they come from the ponds
and go to the thalamus,
and then the cortex happens all over the brains.
And that is where glutamate,
which is a major excitatory neurotransmitter involved
in learning and plasticity is being released
in big amounts also in those distal dendrites.
So P waves and spindles work together to cause plasticity
and sew our schema together,
which could be the origins for insight and creativity.
Now when PGO waves or P waves are first discovered,
it was thought to be random,
because this small area that generates pee waves all over the brain,
you know, projects all over the thalamus and causes p waves all over.
And you don't measure P waves all over the brain at the same time.
In fact, it just seems sporadic and random.
So that's probably, and P waves are also happening even more during REM sleep,
rapid eye movement sleep.
So that's probably, that's why people think that REM dreams are so random is because these
P waves are random and they could generate dreams because they're an internal source of
excitation that kind of replaces the outside world during our dream state. And so these P waves,
if they are random, could function, or could be the underlying reason why REM sleep dreams are
random. And it might also be why creativity can happen there is because we're randomly activating,
co-activating different things in our brain that we can then sew together.
But it might not be as random as we think.
So that's a caveat there.
I just learned a lot from you because I teach brainstem to medical students
and I talk about the ponds.
And the ponds is like this dense collection of all these different nuclei involved in a bunch
of different things and it's close by a bunch of interesting things.
And it's still kind of a mysterious brain area.
But when I learned about PGO waves, I thought ponds, geniculate, oxenic.
occipital because occipital is most commonly associated with visual cortex.
I thought it was the origin of the visual component of dreams.
It probably is.
I'm very happy to learn that they should be called P-waves
because they include lots of different areas of the brain.
And it makes really good sense to me why the kind of pseudo-randomness of dreams,
especially these late night or early morning, later in sleep, I should say,
and early morning dreams seem to be cobbled together,
from disparate experiences.
You walk through a door and suddenly it's a completely different context and landscape.
Yes, beautiful.
Yeah, I like this idea a lot.
It makes intuitive sense.
It makes biological sense.
It also gives me something to talk about to the medical students next quarter when I talk
about ponds.
You want to talk about where in the ponds?
It's right below the locus surrelus.
It's called the sub-surrelus.
They're glutametergic.
It's also called S-L-D sublateral dorsal nucleus.
So, love it. So note to any aspiring neurobiologists, there's a vast landscape of yet to be
undiscovered structure and functions in the ponds. You want to work on something that is sure to
reveal something novel, work on the ponds. Because it's in every textbook. It's a clinically very
important structure. Sadly, gliomas can, and other cancers of the brain can sometimes, can often
surface in the ponds. But we still know very little about it.
I read a paper this last year or, and I think it was covered in a bit of popular press,
that during rapid eye movement sleep, people can solve problems or respond to external stimuli.
Like, for instance, they would give them math problems.
They'd whisper in their ear while they were in REM sleep.
You know, what's 2 plus 2?
And people would say, even though they were paralyzed, apparently they could still move their mouth
because they'd say, four or something like that.
Or they'd say, you know, what's your name and people could respond?
And so that in REM sleep, perhaps people, some elements of cognition are still active.
I'm glad you brought that out.
What do you think of? And I don't know the authors of that study.
And listen, if ever I say something wrong, it's great on this podcast because someone will tell us in the YouTube comments.
It's one of the great uses of YouTube comments.
But I'd love to know your thoughts on that study.
I mean, is that just kind of an odd feature?
Or does this have meaning?
Should we actually care about this result?
There's no just about it.
It's really actually intriguing and interesting and might relate to this paper that I talked about
where we said different areas of the brain can be in different states at the same time.
So lucid dreaming is another thing we can't ask animals to do or can't ask them if they've done it,
but we can certainly ask humans to do it and some people can do it really well.
And it would be really interesting to see in those people who could lucid dream really well,
whether they spend more or less time in this asymmetrical state where one area the brain is in one state
and another area the brain is in another. And it might be that those people can respond to questions
during REM sleep best are those that have the most asymmetry or dissimilarity or dissociation
between subcortical and cortical structures. Or it might be that they're the ones with the most
symmetry. We don't know. I do worry a little bit about lucid dreaming because people are
It's a fad.
People are really excited about it.
And to be able to remember one's dreams is fun often, unless they're nightmares.
But it's really interesting.
Or to be able to direct one's dreams, if they are nightmares,
is really wonderful power to have to be able to redirect a nightmare that has been repeated to something else
and then kick yourself out of that repetitive nightmare is really nice.
But I worry a little bit about because we know so little about what's actually going on in the brain.
And if this lucid dreaming state is preventing us from, for example, from the locus
realis from calming down or the serotonergic system from silencing like it should, and maybe what
we're doing during this state is, yeah, we're activating the learning and memory structures,
but in a way that's maladaptive in terms of the erasure that we need to do.
So maybe one of the reasons why most people don't remember most of their dreams is for good
reason.
Your hippocampus is in a state where it's not writing new memories.
In fact, it's writing out the memories it learned during the day to the cortex, and it's
immune from incoming new information.
So maybe lucid dreaming is bad because you're activating the hippocampus in a way that's writing
new memories, and it might be really maladaptive for things like PTSD.
On the other hand, let me just argue myself right out of this.
When I used to have a repeated nightmare, when I was a kid, my mother was so wise,
would tell me, well, listen, just next time you're in that dream, you know, say, hey, I'm in a dream
and then change something about it. So she and I rehearsed what the horrible dream that it was.
It was a big monster, you know, running after me and my legs were like mud, and I couldn't run away,
and it was just terrifying. And that was a dream I would have, you know, time and time again.
She said, okay, next time, what are you going to do? And that monster comes after you.
I'm going to run away. No, that's what you do every time. And it's always the same outcome.
you can't run. So let's do something different. Like what could you do that's different? So I came up with,
well, I could turn around and punch it in the nose. Yeah, that's great. So the next time I had that dream,
I did recognize this is that same old dream, which means that there's part of my brain that's
conscious enough to know that I'm in a dreaming state. And then I didn't have the courage in my dream
because I was still terrified to punch or touch the monster in any way. But I did have the courage to turn around
and look it in the eye and say, no, that was enough.
I said, no.
And that was enough to knock me out of that rut of that dream so that I never had it again.
I never had that same dream again.
And in fact, it gave me peace about dreaming because I knew that if ever there was a nightmare
that was just too scary, I could probably do something to change it and knock myself out of it.
So even though I don't recommend lucid dreaming on a normal day-to-day basis, if it's enough
that can knock you out of a rut.
One thing that happens with people with PTSD
is they have the same repeated horrible nightmare,
which is often a reliving of the day's trauma that they had.
So maybe lucid dreaming can be used on occasion
to be a powerful tool,
because there's so much plasticity that happens during REM sleep,
to knock you out of that rut of reliving that event
and just change it.
And you could probably practice that during wakefulness,
rehearse the event that happened that was so traumatic,
and then just introduce a new element, like, you know, now I'm safe.
Now, you know, the sound that was associated with that really traumatic thing,
I should now associate with something else.
And next time I have that dream, I'm going to change it.
So that sound is now this new thing that it should be associated with safety.
And that might be enough, maybe, I hope, to,
knock you out of that repeated nightmare and maybe even start you on the path to recovery
because if you can calm down about those nightmares states of sleep, then maybe your locus
Cyrillus, which is involved in stress, can also relax and you can do the erasure parts that
need to be done.
I love it.
I seem to recall a paper, and I'll have to find the reference and send it to you.
We will also put in the show note captions that described a protocol essentially matches this idea
and I think what they had people do
is either cue themselves to a particular smell
or tone in wakefulness,
then to try and recall a recurring nightmare.
Then during the night's sleep,
they had the tone playing in the background,
which would then cue them to the wakeful state.
They're still asleep, mind you,
but in the pseudo-lucid or lucid state
and then try and change some variable,
as you're describing.
Some either look at the predator in the eyes
or do something different.
And then in the waking state,
take a little bit of time to try and script out a different narrative altogether.
And it took several nights, as I recall, or more, but that they were able to escape this recurring
nightmare.
It was like a week or something.
So you're familiar with this study.
Yeah, that's a beautiful study.
I loved it.
Yeah.
We will put a reference to that.
I need to revisit that.
It was pretty recent, but I need to dive into it again because I think I didn't go
as deep into it as I should have.
No, no, but the one thing that you said many right things, but one of the things you
said is that they were able to cue the dreamer when they knew and they were going to REM sleep
and then they played the sound or had the odor. Now, when you're normally asleep alone in your
bed, you're not going to be able to cue yourself. But it might be that rehearsal enough before
you go to sleep is enough to, you know, help cue you to that repeated nightmare. Remembering what
the nightmare is and then figuring out how to cue yourself to do something different.
For years, I had the same recurring nightmare.
over and over and over again.
And it was so salient and so clear.
And I'm not going to share what it is because it's not that it's that disturbing.
It was just I think it was the emotional load of it and just how salient certain features were.
Like one person who's a real life person had a particular clothing on.
And it's like, and that just served as this cue.
And I don't know if I ever did any direct work to try and deal with it.
But now it almost seems silly to describe it.
Oh, yeah.
Well, dreams are usually silly to describe it.
Pretty silly.
But it was a pretty violent dream.
Yeah.
And your emotional system is so geared up during REM sleep, which is another thing we
could talk about.
Yeah, please.
I would love to.
Yeah, so Locus Cirulius is ideally suppressed.
So we can't release nor epinephrine.
We can't act out our dreams.
This during these very emotionally laden thoughts and storylines during sleep, this is almost
starts to sound like a little bit of a built-in, wow.
sleeping trauma therapy because most trauma therapies involve trying to get people into states of
counter to what most people think you actually want to get close to the trauma in terms of the
narrative but try and suppress the emotional activity of it or I guess that's the motivation for ketamine
based therapies for trauma or I've also heard and this is still perplexing to me that other
waking based trauma therapies involve taking people the other way making it very cathartic
take them to the peak of the emotional response but then allow that to finally
cycle down into a more relaxed response.
So please, if there's anything about Locus Cirulius and dreams that can help people
basically extinguish traumas or traumatic features to real-life events, and we definitely
want to know about them.
Yeah, yeah.
Well, I think one of the things that people thought might help after a trauma, like a school
shooting or whatever car accident is to talk about it.
But in fact, that ended up being counterproductive.
And I think one of the reasons why it was counterproductive is because it didn't take them back down.
It brought them up and continued to reactivate the emotions of it, but then didn't, you know,
emphasize the safety effect that it's over or help them work through how they might avoid it again in the future
to calm the sympathetic nervous system down again before they went to sleep.
And none of these studies has sleep ever been considered.
But to me, that's the key part is bringing down your sympathetic nervous system before you go to sleep so that your sleep can be adaptive.
Your locuserilus can shut off like it normally does or should do and then able to erase the novelty of it.
The other thing that I just mentioned a minute ago was that the emotional system is highly activated in REM sleep.
And that's definitely true.
And that might seem counterproductive in terms of, you know, the nightmares.
and how to help REM sleep be a therapeutic thing rather than in reinforcing the
emotionality of the trauma.
And I think the key to that again is the absence of noraphenephyran.
So even though the emotional system is in high gear, without noraphyne, you can actually
divorce those highly activated emotions from the
cognitive parts of the memory that you have just written out in that N2 stage of sleep when the
sleep spindles are going. So you've just now consolidated the information that you'll need to
survive and to make that adaptive. And now you need to divorce from that schema and from that semantic
parts of memory, the emotional part. Because whenever you remember something, it's fine if you remember
being emotional at the time, but you don't want to bring back and so into that memory all of the
same emotional systems. You don't want to bring back, you know, the heart rate changes and the
sweating and all of that. You want to be able to remember all the parts of it and even remember
that you were traumatized and that you did cry and that you did have, you know, your heart was
racing. But when you're talking about it, years later, you don't want to have to relive all that.
Otherwise, who would ever want to recall a dramatic memory because you're basically putting yourself through the same trauma, which is what people with PTSD have.
They don't want to recall this traumatic memory because it's reliving it like it's just happening again.
So that's what we're thinking is that the emotional parts are not able to be divorced because the Noroprenorphine system is not downscaled during REM sleep.
And so that REM sleep serves to instead reinforce and, in fact, amplify the emotions because your emotional system is up.
Locus Cyrillus is high, re-sewing in every night the emotionality of those memories and with the memory itself.
You told us a lot about locusyrelius and noraphenephyrin from locusyroelius.
Is there any role for noraphyran, epinephrine, and cortisol released from the adrenal.
My understanding is that norapinephrine and epinephrine will not cross the blood brain barrier,
which is probably why we have a brain-based neuroadrenergic system, locuserulius and other neurons.
Actually, that's a question I should ask you.
Are there other sites in the brain where neuropinephrine is released from, or is it just locus serulias?
So there are seven, nine different adrenergic, yes.
There's nine different adrenergic structures.
I should know this.
I'm sorry.
I've been asked, but it just occurred to me that in some cases, like with Rafé, there are other
sources of serotonergic drive in the brain, but Rafé is like the main.
Yeah, that's the one that goes to the cortex and the locus aerosurals is also the one that
goes to the cortex.
But there are other adenergic sources, some that from the brainstem that descend and help
us to ignore pain, for example, when we're stressed and needing to run away from the tiger,
right?
We don't want to be thinking, oh, my ankle hurts.
You know, you want to just be able to ignore it and go do what you need to do.
So, yeah, so there are lots of other neurodinergic nuclei,
but the locustrialist is the main one that projects all over the brain.
Actually, the only place that doesn't project is the dorsal striatum.
You talked about ventral striatum and addiction.
The dorsal striatum is the only place the locus serlis doesn't project to,
and that's involved in procedural learning, motor learning,
the kinds of learning that take over when your hippocampus, for example, is compromised.
Bilateral if you don't have a good hippocampus, you can still do procedural learning and it's great.
It's a redundant system.
And so if your locustralist is not working, if you don't have it anymore, you can still do, if you don't have a good hippocampus,
you can still do learning through this dorsal stratum structure.
So it might be for those kinds of learning functions, sleep deprivation, where you never
the locus real stop firing is okay because it doesn't have any receptors for norapherin
anyway so yeah and what about bodily um like adrenals yeah um you know i i often remind people there's
no such thing as adrenal burnout per se that adrenals don't actually um burn out um but some people have
adrenal insufficiency syndrome other people have adrenals that are just chronically cranking out
epinephrine, noropenephrine, and cortisol at the wrong times in particular.
Yeah, yeah.
So those are great questions, and I think the answers to them have yet to be discovered,
the connections between our periphery and our central nervous system.
But we know that there are beautiful connections, and it's untapped source of being able
to manipulate our brains is to work through our bodies.
And so our adrenals do great things.
They constrict our blood vessels, causing higher blood pressure, which help blood rush out to all the extremities that need blood.
Our muscles, for example, for running away from the lion or the tiger.
Or meeting a grant deadline.
Or catching a train.
Or catching a train, yeah.
The adrenals help our hearts bump faster.
Our muscles get profused with the blood it needs.
It diverts blood and everything away from our.
parasympathetic system, which is rest and digest.
We don't really need to digest that croissant when we're running for a train.
We can do that later.
So it's doing really important things.
What we don't know because it doesn't cross the blood-brain barrier is how that affects
the brain and whether our, if we can independently activate our adrenals,
when a time when our brain thinks that we should be fine and calm and asleep,
how our brain detects that.
Is it a feedback through our heart is racing
and then our brain stance says,
what's going on?
My heart is racing and then wakes us up.
And then our hearts were racing together
with our brain racing.
We just don't know the answers to these questions yet.
There are some good studies, old studies,
but we need a lot more.
I will another nod to the fact
that there's lots of great work ongoing and still to do.
I'd love for you to tell us.
us about some of the work that you're doing more recently on the relationship between sleep and
opiate use withdrawal relapse and craving just addiction generally i get a lot of questions about
people trying to come off benzodiazepines or um people's challenges with benzodiazepine and other
types of addiction um yeah what what is the role of sleep in addiction and recovery from addiction and
opiates in particular. Yeah. This is a very young area. And in fact, my laboratory has just
started. I have a graduate student who's been in my lab for just one year. She's done amazing work
already, but completely groundbreaking work. And what she has discovered already, we don't have
the paper out yet, but we're working on it, is that when animals withdraw from opiates,
and this has been sort of replicated in other ways with other types of things.
Our sleep is disturbed.
Our sleep is terribly disturbed.
And the amount of sleep disturbance predicts relapse behaviors.
And you might think, well, of course, you're going to relapse if you can't sleep because
opiates calm you down.
Well, one of the reasons why opiates calm you down is because the locus arrolus, again,
loose spot is covered with opiate receptors that are normally really responsive to our
endogenous opiates.
And so what happens when we're pleased, for example, or laughing or whatever, and dodges opiates,
activate those receptors in the locus relis and calm it down.
And it actually suppresses locus relis activity, makes us happy and relaxed.
One of the reasons why opiates are so addictive is because it also calms us down and makes us relaxed.
But the problem with exogenous opiates is that they really strongly bind,
these receptors on our locusyrilis. And if you take exogenous opiates again and again,
like you're recovering from surgery, for example, take these pain medications, is that our locus
rilus struggles to do what it's supposed to do, which is keep us awake and learning and concentrating
on things. So it will downregulate. It will internalize these receptors that are normally only
occupied by endogenous opiates. And it will do this. It will change our genes that are associated
with producing these receptors, so you actually have very many fewer receptors.
So the locus rilus, at least during wakefulness, can fire and to help us to do these things
like learn about our environment.
And so if you long-term reduce the number of receptors out there, then when you withdraw
the exogenous opiates, there is not enough of your endogenous opiates to be able to occupy
those few receptors that are there, and our locust realist has nothing to calm it down anymore,
no pacifier. And it just fires and fires and fires. And that phasic and tonic high activity
stresses us out because it's normally associated with stress. And so any exogenous stressor
that adds to that and it also activates our locus rilis, there's nothing to calm it down again.
And so it just keeps firing. It disturbs our sleep. And that's why maybe sleep disturbance is
an indicator of hyperactive locusyreelis and such a good predictor of relapse behaviors because
nobody likes to live in that high stress state and they'll do anything to get back to normal.
So the problem with taking these drugs is that it leaves you excited and, sorry,
excited, relaxed and happy, but then when you come off of it, you're worse than when you wear
it baseline. You take it again. It only brings you up this far because you have fewer receptors.
When you come off it, you're down even more depressed and anxious and depressed as a word I use loosely,
and that's not what I should say. Certainly central nervous system depression. I mean, sleepier,
less motivated, lowered mood. Yeah, I mean, our locus surrealis is actually, it's the anxiety
kind of depression, actually the anxiety-related depression. So yeah, so we don't know yet what,
and there's some good research going on right now, what could restore our own endogenous receptors
so that our own dogenous opiates can properly calm or locusyrilis, once that they have been
tamped down by exogenous opiates, but that would be really one way that you can access
the sleep disturbance. So we talked about sleep and the importance of sleep in terms of
learning and memory, the importance of the structure of the 90-minute cycle for all of that.
So you can imagine if your sleep is disturbed by too much locust or else activity,
the structure and the function of those sleep spindles and that theta during REM sleep
and the lack of norapherine, all of those structures, all those functions for learning,
something new like a new behavior that as it involves the drugs becomes compromised.
that's something that Tanya Lugos, in collaboration with Pamela Kennedy at UCLA, that we're looking at,
how is learning and memory affected by the sleep disturbance? If there are a way we can, in animals
that have coming off of opiates, can we restore their sleep to normal so that then they are
less likely to do relapse kinds of behaviors?
Fascinating. And I will certainly have to have you back on to tell us the results of those
studies. Meanwhile, I think for anyone who's trying to comb off opiates, exogenous opiates and restore
these systems, what I'm hearing is that it's going to take some time, but that any and all
things that people can do to buffer their healthy, normal sleep architecture, like morning and
daytime sunlight, limiting bright light exposure, lowering the temperature at night, a number of
things that we've talked about on this podcast. Calming before sleep.
Meditation, whatever it is that helps you calm yourself before sleep, yeah.
Right. Would facilitate not just
sleep, but perhaps even accelerate the recovery and shorten this period of withdrawal, which
from the questions I get and from what I hear can be absolutely brutal.
Yeah.
Oh, I can imagine.
I had to take opiates for, I only took it for three days after giving birth to my first son,
I think, second son, one of them.
And I just said after three days, this is enough.
I'm just going to try Tylenol.
And so I weaned myself, not weaned.
I just did a sudden sharp cutoff.
And even though I felt I didn't get the high of opiates when I was taking the Tylenol codeine, when I went off it, boy, it was like PMS times 100.
I was so anxious and upset at little things.
Thankfully, only lasted a few hours.
But if I had taken it for a week or two weeks, who knows if my endogenous opiate receptor,
would have been permanently downregulated and I would have been an addict, you know,
an addict, I would have been addicted.
I shouldn't say an addict.
There's negative connotations.
It's just a very physiological state.
So no judgments at all associated with it.
So, yeah, they're powerful, powerful painkillers, but can also alter your entire brain and
rewire it.
Well, all the more reason why I and many others are grateful that you're doing this work
to figure out ways that people can recover.
more quickly and more thoroughly.
I must say you've taught us a tremendous amount in a relatively short amount of time
about the architecture of sleep, the different phases,
the relationship between sleep and dreaming and this incredible structure, Locus Cirulius,
and I'm so happy we also got into the ponds that just delights me
because we rarely talk about the ponds on this podcast,
but it's such an interesting structure.
Sex differences that are important in creativity and problem solving
and trauma, sleep spindles, just such a wealth of information and much of it that's actionable
for people.
So, first of all, I want to say thank you for taking the time to sit down and have this
conversation that so many people are sure to benefit from.
I also want to thank you for doing the work you do, even though I'm a fellow neurobiologist.
I think that it's not often that we take a step back and realize that it's really the work
of hard thinking, hard, strongly.
motivated PIs, it stands for principal investigator, by the way, PIs like yourself,
graduate students and postdocs that really drive the discovery forward and that lead to these
new therapeutics.
Physicians are wonderful.
Clinicians are absolutely wonderful, but clinicians don't develop new treatments.
They only implement the ones that researchers discover.
So thank you for being a brain explorer with a focus on growing the good in the world.
I know I speak for everybody when I say thank you so much.
Thank you so much, Andrew.
Thank you for being an amazing interviewer.
You brought a lot out of me in a coherent fashion that normally I can't do when I'm speaking
in public.
I don't know about that.
I've heard your lectures and they're superb.
We'll direct people to some of the other ones.
Well, thank you.
And I also want to put a plug in for graduate students in general and the key and amazing
role that they play in research.
I'm a PI, as you said.
I used to be a graduate student and a postdoc trainee myself doing all of this on the ground,
hands-on experimentation.
so hard to do. It's so hard to do right. It's so hard to think through all of that. Now I'm a PI.
I get to be an idea person and just say, hey, why don't you do this? And hey, you know,
what do you think about that? And they, of course, intellectually contribute so much to these
these planned experiments, but they also do the really hard work. And so I just want to say,
thank you, graduate students. Thank you to my graduate students and all graduate students out
there. Thank you, postdocs.
paid and to the major institutions, Stanford, UCLA and all other major institutions, pay them more, please.
We need them and they need to have a standard of living. I'm not afraid to say that, despite my
primary employer. Pay them more. They need it. They deserve it. Absolutely.
Great. Well, we will absolutely have you back again if you'll be willing. And meanwhile,
we will direct people to where they can learn more about you and your exciting work. And once again,
thanks so much. Thank you so much. Thank you for joining me today.
for my discussion about sleep, mental health, physical health, and performance with Dr. Gina Poe.
I hope you found it to be as informative and as actionable as I did. In fact, I'm already implementing
the regularity of bedtime plus or minus half an hour in order to get that growth hormone release.
And I can already see both my sleep scores improving and my feelings of daytime vigor and focus
and other markers of sleep health improving as well. If you're learning from Endor and Join
this podcast, please subscribe to our YouTube channel. That's a terrific zero cost way to support us.
In addition, please subscribe to the podcast on both Spotify and Apple.
And on both Spotify and Apple, you can also leave us up to a five-star review.
If you have questions for us or comments or suggestions about guests you'd like me to include
on the podcast, please put those in the comment section on YouTube.
I do read all the comments.
In addition, please check out the sponsors mentioned at the beginning and throughout today's
episode.
That's the best way to support this podcast.
On the Huberman Lab podcast, we often discuss supplements.
While supplements aren't necessary for everybody, many people derive tremendous benefit
from them for things like a lot.
enhancing the quality and duration of sleep,
for enhancing focus, and for hormone support.
The Huberman Lab podcast is proud to announce
that we've partnered with Momentous supplements.
We've done that for several reasons.
First of all, momentous supplements are of the very highest quality.
Second of all, they mainly focus on single ingredient formulations,
which is absolutely key if you want to develop a supplement regimen
that's most biologically and cost effective.
It, for instance, allows you to alternate dosages across days,
to change the dosages of individual ingredients,
so on and so forth.
In addition, Momentus Supplement ship internationally,
which we know is important because many of you reside
outside of the United States.
If you'd like to see the supplements discussed
on the Huberman Lab podcast, please go to LiveMomenus,
spelled OUS, so that's LiveMomenus.com slash Huberman.
You can get a 20% discount on any of those supplements.
Again, it's livemomentis.com slash Huberman.
The Huberman Lab podcast has a zero cost newsletter
that includes summaries of podcast episodes
and toolkits, so checklists of actionable tools
that you can use for all aspects,
of mental health, physical health, and performance. You can access this completely zero cost by going
to Hubermanlap.com, go to the menu and scroll down to newsletter. Just put it in your email.
We do not share your email with anybody. And you will get our monthly newsletter. And there are also
some examples of previous newsletters also there at Hubermanlap.com. If you're not already
following me on social media, it is Huberman Lab on all platforms, Instagram, Twitter, Facebook,
and LinkedIn. And at all of those places, I cover science and science-related tools,
some of which overlap with the content
of the Huberman Lab podcast,
but much of which is distinct
from the Huberman Lab podcast content.
Again, that's Huberman Lab
on all social media platforms.
Thank you again for joining me
for today's discussion
with Dr. Gina Poe,
all about sleep
and its relationship
to mental health,
physical health, and performance.
And last, but certainly not least,
thank you for your interest in science.