Huberman Lab - Essentials: How to Focus to Change Your Brain
Episode Date: December 19, 2024In this Huberman Lab Essentials episode, I explain how neuroplasticity allows the brain to continue to adapt and change throughout life, particularly through focused attention and active engagement in... learning. I explain how neuroplasticity differs in children and adults, highlighting the key neurochemicals required for adult learning. I explain science-supported protocols to boost alertness and improve attention, including techniques like visual focus and goal accountability. I also discuss how sleep, along with practices such as non-sleep deep rest (NSDR) and naps, support the brain to enhance learning. Huberman Lab Essentials are short episodes (approximately 30 minutes) focused on essential science and protocol takeaways from past Huberman Lab episodes. Essentials will be released every Thursday, and our full-length episodes will still be released every Monday. Read the full show notes at hubermanlab.com. Thank you to our sponsors AG1: https://drinkag1.com/huberman David: https://davidprotein.com/huberman LMNT: https://drinklmnt.com/huberman More Huberman Lab Huberman Lab Premium: https://go.hubermanlab.com/premium Huberman Lab Merch: https://go.hubermanlab.com/merch Timestamps 00:00:00 Huberman Lab Essentials; Neuroplasticity 00:03:27 Sponsor: David 00:04:43 New Neurons; Sensory Information, Brain & Customized Map 00:07:40 Recognition, Awareness of Behaviors 00:09:58 Sponsor: AG1 00:11:06 Attention & Neuroplasticity 00:15:40 Epinephrine, Acetylcholine & Nervous System Change 00:18:20 Improve Alertness, Epinephrine, Tool: Accountability 00:20:39 Improve Attention, Acetylcholine, Nicotine 00:23:09 Sponsor: LMNT 00:24:26 Tool: Visual Focus & Mental Focus 00:29:54 Tool: Ultradian Cycles, Anchoring Attention 00:31:00 Sleep & Neuroplasticity; NSDR, Naps 00:33:34 Recap & Key Takeaways 00:36:38 Zero-Cost Support, YouTube, Spotify & Apple Follow & Reviews, Recommendations, Sponsors Disclaimer & Disclosures
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Welcome to Huberman Lab Essentials,
where we revisit past episodes
for the most potent and actionable science-based tools
for mental health, physical health, and performance.
My name is Andrew Huberman,
and I'm a professor of neurobiology and ophthalmology
at Stanford School of Medicine.
Today, we're talking about neural plasticity,
which is this incredible feature of our nervous systems
that allows it to change in response to experience.
Neuroplasticity is arguably one of the most important aspects
of our biology.
It holds the promise for each and all of us
to think differently, to learn new things,
to forget painful experiences,
and to essentially adapt to anything that life brings us by becoming better.
So let's get started. Most people are familiar with the word neural plasticity,
which is the brain and nervous systems ability to change itself.
All of us were born with a nervous system that isn't just capable of change,
but was designed to change. When we enter the world,
our nervous system is primed for learning.
The brain and nervous system of a baby
is wired very crudely.
The connections are not precise.
And we can see evidence of that in the fact that babies
are kind of flopping there,
like a kind of a little potato bug with limbs.
They can't really do much in terms of coordinated movement.
They certainly can't speak
and they can't really do anything with precision.
So I want you to imagine in your mind
that when you were brought into this world,
you were essentially a widely connected web of connections
that was really poor at doing
any one thing.
And that through your experience,
what you were exposed to by your parents or other caretakers
through your social interactions, through your thoughts,
through the languages that you learned,
through the places you traveled or didn't travel,
your nervous system became customized
to your unique experience.
Now that's true for certain parts of your brain
that are involved in what we call representations
of the outside world.
A lot of your brain is designed
to represent the visual world
or represent the auditory world
or represent the gallery of smells
that are possible in the world.
However, there are aspects of your nervous system
that were designed not to be plastic.
They were wired so that plasticity or changes
in those circuits is very unlikely.
Those circuits include things like
the ones that control your heartbeat,
the ones that control your breathing,
the ones that control your digestion.
And thank goodness that those circuits were set up that way
because you want those circuits to be extremely reliable.
So many nervous system features like digestion
and breathing and heart rate are hard to change.
Other aspects of our nervous system
are actually quite easy to change.
And one of the great gifts of childhood,
adolescence and young adulthood
is that we can learn through almost passive experience.
We don't have to focus that hard
in order to learn new things.
And then after age 25,
if we want to change those connections,
those super highways of connectivity,
we have to engage in some very specific processes.
And those processes, as we'll soon learn, are gated,
meaning you can't just decide to change your brain.
You actually have to go through a series of steps
to change your internal state
in ways that will allow you to change your internal state in ways
that will allow you to change your brain.
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Many of us have been captivated by the stories
in the popular press about the addition of new neurons,
this idea, oh, if you go running or you exercise,
your brain actually makes new neurons.
Well, I'm going to give you the bad news,
which is that after puberty,
the human brain and nervous system adds very few,
if any, new neurons.
So even though we can't add new neurons
throughout our lifespan, at least not in very great numbers,
it's clear that we can change our nervous system,
that the nervous system is available for change,
that if we create the right set of circumstances
in our brain, chemical circumstances,
and if we create the right environmental circumstances
around us, our nervous system will shift into a mode
in which change isn't just possible, but it's probable.
As I mentioned before, the hallmark
of the child nervous system is change.
It wants to change.
One of the ways in which we can all get plasticity
at any stage throughout the lifespan
is through deficits and impairments
in what we call our sensory apparatus,
our eyes, our ears, our nose, our mouth.
In individuals that are blind from birth,
the so-called occipital cortex,
the visual cortex in the back becomes overtaken by hearing.
The neurons there will start to respond to sounds
as well as braille touch.
And actually there's a one particularly tragic incident
where a woman who was blind since birth
and because of neuroimaging studies,
we knew her visual cortex was no longer visual,
it was responsible for braille reading and for hearing.
She had a stroke that actually took out
most of the function of her visual cortex.
So then she was blind, she couldn't Braille read or hear.
She did recover some aspect of function.
Now, most people,
they don't end up in that highly unfortunate situation.
And what we know is that, for instance,
blind people who use their visual cortex
for Braille reading and for hearing
have much better auditory acuity and touch acuity,
meaning they can sense things with their fingers meaning they can sense things with their fingers
and they can sense things with their hearing
that typical sighted folks wouldn't be able to.
In fact, you will find a much greater incidence
of perfect pitch in people that are blind.
And that tells us that the brain,
and in particular this area we call the neocortex,
which is the outer part,
is really designed to be a map
of our own individual experience.
So these, what I call experiments of impairment or loss,
where somebody is blind from birth or deaf from birth,
or maybe has a limb development impairment
where they have a stump instead of an entire limb
with a functioning hand,
their brain will represent the body plan that they have a stump instead of an entire limb with a functioning hand, their brain will represent the body plan that they have,
not some other body plan.
But the beauty of the situation
is that the real estate up in the skull, that neocortex,
the essence of it is to be a customized map of experience.
A few years ago, I was at a course and a woman came up to me and she said, I wasn't teaching the ago, I was at a course
and a woman came up to me and she said,
I wasn't teaching the course, I was in the course.
And she said, I just have to tell you
that every time you speak, it really stresses me out.
And I said, well, I've heard that before,
but do you want to be more specific?
And she said, yeah, your tone of voice reminds me
of somebody that I had a really terrible experience with.
I said, well, okay, well, I can't change my voice,
but I really appreciate that you acknowledge that.
And it also will help explain why you seem to cringe
every time I speak, which I hadn't noticed until then.
But after that, I did notice she had a very immediate
and kind of visceral response to my speech.
But in any event, over the period of this two week course,
she would come back every once in a while and say,
you know what, I think just by telling you
that your voice was really difficult for me to listen to,
it's actually becoming more tolerable to me.
And by the end, we actually became pretty good friends
and we're still in touch.
And so what this says is that the recognition of something,
whether or not that's an emotional thing
or a desire to learn something else,
is actually the first step in neuroplasticity.
If I get up out of this chair and walk out of the door,
I don't think about each step that I'm taking
and that's because I learned how to walk during development.
But when we decide that we're going to shift
some sort of behavior or some reaction
or some new piece of information that we want to learn
is something that we want to bring into our consciousness,
that awareness is a remarkable thing
because it cues the brain and the rest of the nervous system
that when we engage in those reflexive actions
going forward, that those reflexive actions
are no longer fated to be reflexive.
Now, if this sounds a little bit abstract,
we're going to talk about protocols for how to do this.
But the first step in neuroplasticity is recognizing
that you want to change something.
We have to know what it is exactly that we want to change.
Or if we don't know exactly what it is
that we want to change,
we at least have to know that we want to change something
about some specific experience.
Now there are specific protocols that science tells us
we have to follow if we want those changes to occur.
What it is, is it's our forebrain,
in particular our prefrontal cortex,
signaling the rest of our nervous system
that something that we're about to do here,
feel or experience is worth paying attention to.
So we'll pause there and then I'm going to move forward.
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One of the biggest lies in the universe
that seems quite prominent right now
is that every experience you have changes your brain.
People love to say this.
They love to say, your brain is going to be different
after this lecture, or that your brain is going to be
different after today's class than it was two days ago.
And that's absolutely not true.
The nervous system doesn't just change
because you experienced something
unless you're a very young child.
The nervous system changes
when certain neurochemicals are released
and allow whatever neurons are active in the period
in which those chemicals are swimming around
to strengthen or weaken the connections of those neurons.
So when people tell you,
oh, at the end of today's lecture,
at the end of something,
your brain is going to be completely different,
that's simply not true.
If you're older than 25, your brain will not change
unless there's a selective shift in your attention
or a selective shift in your experience or a selective shift in your experience
that tells the brain it's time to change.
And those changes occur through strengthening
and weakening of particular connections.
But the important thing to understand
is that if we want something to change,
we really need to bring an immense amount of attention
to whatever it is that we want to change.
This is very much linked to the statement I made earlier
about it all starts with an awareness.
Now, why is that attention important?
In the early 90s, a graduate student
by the name of Greg Reckonzon was in the laboratory
of a guy named Mike Merzenich at UCSF.
And they set out to test this idea
that if one wants to change their brain,
they need to do it early in life
because the adult brain simply isn't plastic.
It's not available for these changes.
And they did a series of absolutely beautiful experiments.
By now, I think we can say proving
that the adult brain can change
provided certain conditions are met.
Now, the experiments they did are tough.
They were tough on the experimenter
and they were tough on the subject.
I'll just describe one.
Let's say you were a subject in one of their experiments.
You would come into the lab and you'd sit down at a table
and they would record from or image your brain
and look at the representation of your fingers,
the digits as we call them.
And there would be a spinning drum,
literally like a stone drum in front of you
or metal drum that had little bumps.
Some of the bumps were spaced close together,
some of them were spaced far apart.
And they would do these experiments
where they would expect their subjects
to press a lever whenever, for instance,
the bumps got closer together or further apart.
And these were very subtle differences.
So in order to do this,
you really have to pay attention
to the distance between the bumps.
And these were not Braille readers
or anyone skilled in doing these kinds of experiments.
What they found was that as people paid
more and more attention to the distance between these bumps,
and they would signal when there was a change
by pressing a lever, as they did signal when there was a change by pressing a lever.
As they did that, there was very rapid changes,
plasticity in the representation of the fingers.
And it could go in either direction.
You could get people very good at detecting the distance
between bumps that the distance was getting smaller
or the distance was getting greater.
So people could get very good at these tasks
that you're kind of hard to imagine
how they would translate to the real world
for a non-braille reader.
But what it told us is that these maps of touch
were very much available for plasticity.
And these were fully adult subjects.
What it proved is that the adult brain is very plastic.
And they did some beautiful control experiments
that are important for everyone to understand,
which is that sometimes they would bring people in
and they would have them touch these bumps
on this spinning drum,
but they would have the person pay attention
to an auditory cue.
Every time a tone would go off
or there was a shift in the pitch of that tone,
they would have to signal that.
So the subject thought they were doing something related
to touch and hearing,
and all that showed was that it wasn't just the mere action
of touching these bumps.
They had to pay attention to the bumps themselves.
If they were placing their attention
on the auditory cue on the tone,
well then there was plasticity
in the auditory portion of the brain,
but not on the touch portion of the brain.
And this really spits in the face of this thing
that you hear so often,
which is every experience that you have
is going to change the way your brain works.
Absolutely not.
The experiences that you pay super careful attention to
are what open up plasticity
and it opens up plasticity to that specific experience.
So the question then is why?
And Merzenich and his graduate students and postdocs
went on to address this question of why.
And it turns out the answer
is a very straightforward neurochemical answer.
And the first neurochemical is epinephrine, also adrenaline.
We call it adrenaline when it's released
from the adrenal glands above our kidneys,
that's in the body.
We call epinephrine in the brain,
but they are chemically identical substances. Epinephrine is released from a's in the body. We call epinephrine in the brain, but they are chemically identical substances.
Epinephrine is released from a region in the brainstem
called locus coeruleus.
Epinephrine is released when we pay attention
and when we are alert.
But the most important thing for getting plasticity
is that there be epinephrine, which equates to alertness,
plus the release of this neuromodulator, acetylcholine.
Now, acetylcholine is released from two sites in the brain.
One is also in the brainstem,
and it's named different things in different animals,
but in humans, the most rich site of acetylcholine neurons
or neurons that make acetylcholine
is the parabi-geminal nucleus or the parabrachial region.
All you need to know is that you have an area
in your brainstem and that area sends wires,
these axons up into the area of the brain
that filters sensory input.
So we have this area of the brain called the thalamus
and it is getting bombarded
with all sorts of sensory input all the time.
But when I pay attention to something,
I create a cone of attention,
what we call signal to noise goes up.
So those of you with an engineering background
will be familiar with signal to noise.
Those of you who do not have an engineering background,
don't worry about it.
All it means is that one particular shout in the crowd
comes through, acetylcholine acts as a spotlight.
But epinephrine for alertness,
acetylcholine spotlighting these inputs,
those two things alone are not enough to get plasticity.
There needs to be this third component.
And the third component is acetylcholine released
from an area of the forebrain called nucleus basalis.
If you really want to get technical,
it's called nucleus basalis of Minert.
For any of you that are budding physicians
or going to medical school, you should know that.
If you have acetylcholine released from the brainstem,
acetylcholine released from nucleus basalis and epinephrine,
you can change your brain.
And this has been shown again and again and again
in a variety of papers.
And it is now considered a fundamental principle
of how the nervous system works.
If you can access these three things
of epinephrine, acetylcholine from these two sources,
not only will the nervous system change, it has to change.
It absolutely will change.
And that is the most important thing
for people to understand if they want to change their brain.
So now let's talk about how we would translate
all the scientific information into some protocols
that you can actually apply,
because I think that's what many of you are interested in.
What you do with your health and your medical care
is up to you.
You're responsible for your health and wellbeing.
So I'm not going to tell you what to do or what to take.
I'm going to describe what the literature tells us
and suggests about ways to access plasticity.
We know we need epinephrine.
That means alertness.
Most people accomplish this through a cup of coffee
and a good night's sleep.
So I will say you should master your sleep schedule
and you should figure out how much sleep you need
in order to achieve alertness when you sit down to learn.
But once that's in place, the question then is
how do I access this alertness?
Well, there are a number of ways.
Some people use some pretty elaborate
psychological gymnastics.
They will tell people that they're going to do something
and create some accountability.
That could be really good.
Or they'll post a picture of themselves online
and they'll commit to losing a certain amount of weight
or something like this.
So they can use either shame-based practices
to potentially embarrass themselves
if they don't follow through,
they'll write checks to organizations that they hate
and insist that they'll cash them
if they don't actually follow through.
Or they'll do it out of love.
They'll decide that they're going to run a marathon
or learn a language or something
because of somebody they love
or they want to devote it to somebody.
The truth is that from the standpoint of epinephrine
and getting alert and activated, it doesn't really matter.
Epinephrine is a chemical and your brain does not
distinguish between doing things out of love or hate,
anger or fear.
It really doesn't.
All of those promote autonomic arousal
and the release of epinephrine.
So I think for most people,
if you're feeling not motivated to make these changes,
the key thing is to identify not just one,
but probably a kit of reasons,
several reasons as to why you would want to make
this particular change.
And being drawn toward a particular goal
that you're excited about can be one,
also being motivated to not be completely afraid,
ashamed or humiliated for not falling through on a goal
is another.
Come up with two or three things, fear-based perhaps,
love-based perhaps, or perhaps several of those
in order to ensure alertness, energy
and attention for the task.
And that brings us to the attention part.
Now it's one thing to have an electrode embedded
into your brain and increase the amount of acetylcholine.
It's another to exist in the real world outside
the laboratory and have trouble focusing,
having trouble bringing your attention
to a particular location in space for a particular event.
And there's a lot of discussion nowadays about smartphones
and devices creating a sort of attention deficit,
almost at a clinical level for many people,
including adults.
I think that's largely true.
And what it means, however,
is that we all are responsible for learning
how to create depth of focus.
There are some important neuroscience principles
to get depth of focus.
I want to briefly talk about the pharmacology first,
because I always get asked about this.
People say, what can I take to increase my levels
of acetylcholine?
Well, there are things you can take.
Nicotine is called nicotine because acetylcholine binds
to the nicotinic receptor.
There are two kinds of acetylcholine receptors,
muscarinic and nicotinic,
but the nicotinic ones are involved
in attention and alertness.
I have colleagues.
These are not my kind of like bro science buddies. I have colleagues, these are not my,
you know, kind of like bro science buddies,
I have those friends too.
This is a Nobel Prize winning colleague
who chews Nicorette while he works.
But when I asked him, why are you doing this?
He said, well, increases my alertness and focus.
Now I've tried chewing Nicorette, it makes me super jittery.
I don't like it because I can't focus very well.
It kind of takes me too far up
the level of autonomic arousal.
I've got friends that dip Nicorette all day.
If you're going to go down that route,
you want to be very careful
how much you rely on those all the time,
because the essence of plasticity
is to create a window of attention and focus
that's distinct from the rest of your day.
So what are some ways that you can increase acetylcholine?
How do you increase focus?
The best way to get better at focusing
is to use the mechanisms of focus that you were born with.
And the key principle here is that mental focus
follows visual focus.
We are all familiar with the fact that our visual system
can be unfocused, blurry, or jumping around,
or we can be very laser focused on one location in space.
What's interesting and vitally important to understanding
how to access neuroplasticity
is that you can use your visual focus
and you can increase your visual focus
as a way of increasing your mental focus abilities
more broadly.
So I'm going to explain how to do that.
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Plasticity starts with alertness.
That alertness can come from a sense of love,
a sense of joy, a sense of fear, doesn't matter.
There are pharmacologic ways to access alertness too.
The most common one is of course caffeine.
Many people are now also using Adderall.
Adderall will not increase focus, it increases alertness.
It does not touch the acetylcholine system.
The acetylcholine system and the focus that it brings
is available, as I mentioned through pharmacology,
but also through these behavioral practices.
And the behavioral practices that are anchored
in visual focus are going to be the ones
that are going to allow you to develop great depth
and duration of focus.
So let's think about visual focus for a second.
When we focus on something visually, we have two options.
We can either look at a very small region of space
with a lot of detail and a lot of precision, or we can dilate our gaze
and we can see big pieces of visual space
with very little detail.
It's a trade-off.
We can't look at everything at high resolution.
This is why we have these,
the pupil more or less relates to the fovea of the eye,
which is the area in which we have the most receptors,
the highest density of receptors that perceive light.
And so our acuity is much better in the center
of our visual field than in our periphery.
When we focus our eyes, we do a couple things.
First of all, we tend to do that
in the center of our visual field
and our two eyes tend to align
in what's called a virgins eye movement
towards a common point.
The other thing that happens is the lens of our eye moves
so that our brain now no longer sees the entire visual world
but is seeing a small cone of visual imagery.
That small cone of visual imagery
or soda straw view of the world has much higher acuity,
higher resolution than if I were to look at everything.
Now you say, of course, this makes perfect sense,
but that's about visual attention, not mental attention.
Well, it turns out that focus in the brain
is anchored to our visual system.
I'll talk about blind people in a moment,
but assuming that somebody is sighted,
the key is to learn how to focus better visually
if you want to bring about higher levels
of cognitive or mental focus.
When we move our eyes slightly inward,
maybe you can tell that I'm doing it like,
like so, basically shortening
or making the interpupillary distance
as it's called smaller, two things happen.
Not only do we develop a smaller visual window
into the world, but we activate a set of neurons
in our brainstem that trigger the release
of both norepinephrine,
epinephrine and acetylcholine.
Norepinephrine is kind of similar to epinephrine.
So in other words, when our eyes are relaxed in our head,
when we're just kind of looking
at our entire visual environment,
moving our head around, moving through space,
we're in optic flow, things moving past us,
or we're sitting still,
we're looking broadly at our space, we're relaxed.
When our eyes move slightly inward
toward a particular visual target,
our visual world shrinks, our level of visual focus goes up,
and we know that this relates to the release
of acetylcholine and epinephrine at the relevant sites
in the brain for plasticity.
Now, what this means is that if you have a hard time
focusing your mind for sake of reading or for listening,
you need to practice and you can practice
focusing your visual system.
Now this works best if you practice focusing
your visual system at the precise distance
from the work that you intend to do for sake of plasticity.
So how would this look in the real world?
Let's say I am trying to concentrate
on something related to, I don't know, science.
I'm reading a science paper and I'm having a hard time.
It's not absorbing.
Spending just 60 to 120 seconds,
focusing my visual attention on a small window of my screen,
meaning just on my screen with nothing on it,
but bringing my eyes
to that particular location increases,
not just my visual acuity for that location,
but it brings about an increase in activity
in a bunch of other brain areas that are associated
with gathering information from this location.
So put simply, if you want to improve your ability
to focus, practice visual focus.
Now you may ask, well, what about the experiment
where people were feeling this rotating drum
or listening to the auditory cue,
that doesn't involve vision at all.
Ah, if you look at people who are learning things
with their auditory system,
they will often close their eyes.
And that's not a coincidence.
If somebody is listening very hard,
please don't ask them to look you directly in the eye
while also asking that they listen to you.
That's actually one of the worst ways
to get somebody to listen to you.
If you say, now listen to me and look me in the eye,
the visual system will take over
and they'll see your mouth move,
but they're going to hear their thoughts more,
they're going to hear what you're saying.
Closing the eyes is one of the best ways
to create a cone of auditory attention.
And this is what low vision or no vision folks do.
They have tremendous capacity to focus their attention
in particular locations.
And for most people, vision is the primary way
to train up this focus ability in these cones of attention.
So you absolutely have to focus on the thing
that you're trying to learn.
And you will feel some agitation
because of the epinephrine in your system.
If you're feeling agitation and it's challenging to focus
and you're feeling like you're not doing it right,
chances are you're doing it right.
So once you get this epinephrine, this alertness,
you get the acetylcholine released
and you can focus your attention.
Then the question is for how long?
And in an earlier podcast,
I talked about these ultradian cycles
that last about 90 minutes.
The typical learning bout should be about 90 minutes.
I think that learning bout will no doubt include
five to 10 minutes of warmup period.
I think everyone should give themselves permission
to not be fully focused in the early part of that bout,
but that in the middle of that bout,
for the middle hour or so,
you should be able to maintain focus for about an hour or so.
So that for me means eliminating distractions.
That means turning off the wifi.
I put my phone in the other room.
I encourage you to try experiencing what it is
to be completely immersed in an activity
where you feel the agitation that your attention is drifting,
but you continually bring it back.
And that's an important point,
which is that attention drifts, but we have to re-anchor it. We have you continually bring it back. And that's an important point, which is that attention drifts,
but we have to re-anchor it.
We have to keep grabbing it back.
And the way to do that,
if you're sighted is with your eyes.
That as your attention drifts and you look away,
you want to try and literally maintain visual focus
on the thing that you're trying to learn.
That's the trigger for plasticity.
But the real secret is that neuroplasticity
doesn't occur during wakefulness, it occurs during sleep.
We now know that if you focus very hard on something
for about 90 minutes or so,
maybe you even do several bouts of that per day,
if you can do that, some people can,
some people can only do one focused bout of learning.
That night and the following nights while you sleep,
the neural circuits that were highlighted, if you will,
with acetylcholine transmission will strengthen
and other ones will be lost, which is wonderful
because that's the essence of plasticity.
And what it means is that when you eventually wake up
a couple of days or a week later,
you will have acquired the knowledge forever,
unless you go through some process to actively unlearn it.
So mastering sleep is key
in order to reinforce the learning that occurs.
But let's say you get a really poor night of sleep
after a bout of learning.
Chances are if you sleep the next night
or the following night, that learning will occur.
There's a stamp in the brain
where this acetylcholine was released.
It actually marks those synapses neurochemically
and metabolically so that those synapses
are more biased to change.
Now, if you don't ever get that deep sleep,
then you probably won't get those changes.
There's also a way in which you can bypass the need
for deep sleep, at least partially,
by engaging in what I call non-sleep deep rest,
these NSDR protocols.
But I just want to discuss the science of this.
There was a paper that was published
in Cell Reports last year that shows that if people did,
it was a spatial memory task,
actually quite difficult one where they had to remember
the sequence of lights lighting up.
And if they're just two or three lights
in a particular sequence, it's easy,
but as you get up to 15 or 16 lights
and think numbers in the sequence,
it actually gets quite challenging.
If immediately after, and it was immediately after
the learning, the actual performance of this task,
people took a 20 minute non-sleep deep rest protocol,
or took a shallow nap, so lying down, feet slightly elevated perhaps,
just closing their eyes, no sensory input.
The rates of learning were significantly higher
for that information than were that to just
had a good night's sleep the following night.
So you can actually accelerate learning
with these NSDR protocols or with brief naps,
90 minutes or less.
For many people, letting the mind drift
where it's not organized in thought
after a period of very deliberate focused effort
is the best way to accelerate learning
and depth of learning.
I want to synthesize some of the information
that we've covered up until now.
Today, I want to make sure that these key elements
that form the backbone of neuroplasticity
are really embedded in people's minds.
First of all, plasticity occurs throughout the lifespan.
If you want to learn as an adult, you have to be alert.
It might seem so obvious,
but I think a lot of people don't think about
when in their 24 hour cycle they're most alert.
Just ask yourself,
when during the day do you typically tend to be most alert?
That will afford you an advantage
in learning specific things during that period of time.
So don't give up that period of time
for things that are meaningless, useless,
or not aligned with your goals.
That epinephrine released from your brainstem
is going to occur more readily at particular phases
of your 24- hour cycle than others
during the waking phase, of course.
You should know when those are.
Increasing acetylcholine can be accomplished
pharmacologically through nicotine.
However, there are certain dangers
for many people to do that,
as well as a cost, financial cost.
Learning how to engage the cholinergic system
through the use of the visual system, practicing how long
can you maintain focus with blanks as you need them,
but how long can you maintain visual focus on a target,
just on a piece of paper set a few feet away in the room
or at the level of your computer screen?
These are actually things that people do in communities
where high levels of visual focus are necessary.
What we're really talking about here is trying to harness
the mechanisms of attention and get better
at paying attention.
You may want to do that with your auditory system,
not with your visual system,
either because you're low vision or no vision,
or because you're trying to learn something
that relates more to sounds.
You should also ask yourself whether or not you're trying
to focus too much for too long during the day.
I know some very high performing individuals,
very high performing in a variety of contexts
and none of them are focused all day long.
Many of them take walks down the hallway,
sometimes mumbling to themselves
or not paying attention to anything else.
They go for bike rides, they take walks.
They are not trying to engage their mind
at maximum focus all the time.
Very few people do that
because we learn best in these 90 minute bouts
inside of one of these ultradian cycles.
And I should repeat again that within that 90 minute cycle,
you should not expect yourself to focus
for the entire period of one 90 minute cycle.
The beginning and end are going to be a little bit
flickering in and out of focus.
How do you know when one of these 90 minute cycles
is starting?
Well, typically when you wake up is the beginning
of the first 90 minute cycle, but it does,
it's not down to the minute.
You'll be able to tap into your sense
of these 90 minute cycles as you start to engage
in these learning practices, should you choose.
And then of course, getting some non-sleep deep rest
or just deliberate disengagement,
such as walking or running or just sitting,
eyes closed or eyes open kind of mindlessly,
it might seem in a chair,
just letting your thoughts move around
after a learning bout will accelerate
the rate of plasticity.
And then of course, deep sleep.
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