Huberman Lab - Essentials: How to Learn Faster by Using Failures, Movement & Balance
Episode Date: December 26, 2024In this Huberman Lab Essentials episode, I explain how making mistakes and perceived frustration drive learning and how movement enhances the brain’s adaptability. I explain how making errors trig...gers the release of neurotransmitters, such as dopamine, which are essential for learning. I also discuss the differences between how neuroplasticity occurs in children and adults, focusing on the varying requirements and effort needed for learning. I discuss science-supported learning strategies for adults, including small practice bouts, leveraging frustration, regulating your autonomic state, and using movement to maximize focus and neuroplasticity. 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 BetterHelp: https://betterhelp.com/huberman Timestamps 00:00:00 Huberman Lab Essentials; Learning 00:01:29 Representational Plasticity, Performance Errors 00:03:16 Neuroplasticity, Neurotransmitters 00:05:03 Sponsor: AG1 00:06:11 Visual Adaptation, Children vs. Adults 00:10:23 Errors, Frustration & Neuroplasticity, Adult Learning 00:14:13 Adults, Incremental Shifts vs. High Contingency; Tool: Small Learning Bouts 00:18:43 Sponsor: David 00:20:00 Tool: Ultradian Cycles, Focus, Errors & Frustration 00:22:08 Dopamine, Errors & Subjective Beliefs; Peak Focus; Tool: Frustration 00:25:56 Sponsor: BetterHelp 00:27:02 Limbic Friction; Tool: Behaviors to Increase Alert or Calm 00:30:43 Balance, Errors & Neurotransmitters 00:33:28 Tool: Enhance Neuroplasticity; Movement Disclaimer & Disclosures
Transcript
Discussion (0)
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 going to talk about
how to change your nervous system for the better.
As you recall, your nervous system
includes your brain and your spinal cord, but also all the connections
that your brain and spinal cord make
with the organs of your body,
and all the connections that the organs of your body
make with your brain and spinal cord.
Now, this thing that we call the nervous system
is responsible for everything we know,
all our behavior, all our emotions,
everything we feel about ourselves and the outside world,
everything we think and believe,
it's really at the center of our entire experience
of life and who we are.
Fortunately in humans, unlike in other species,
we can change our nervous system
by taking some very specific and deliberate actions.
And today we're really going to focus on the actions,
the motor commands and the aspects of movement and balance
that allow us to change our nervous system.
It turns out that movement and balance
actually provide windows or portals into our ability
to change our nervous system the way we want,
even if those changes are not about learning new movements
or learning how to balance.
And soon you'll understand why.
So let's talk about the different kinds of plasticity
that are available to us.
Because those will point directly
towards the type of protocols that we should engage in
to change ourselves for the better.
There is something called representational plasticity.
Representational plasticity is just your internal
representation of the outside world.
We know that for instance,
if I want to reach out and grab the pen in front of me
that I need to generate a certain amount of force.
So I rarely overshoot.
I rarely miss the pen.
Okay.
So our maps of the motor world and our maps of the sensory
world are merged.
The way to create plasticity is to create mismatches
or errors in how we perform things.
And this I think is an amazing and important feature
of neuroplasticity that is highly underappreciated.
The way to create plasticity is to send signals
to the brain that something is wrong,
something is different and something isn't being achieved.
Errors and making errors out of sync
with what we would like to do is how our nervous system
is cued through very distinct biological mechanisms
that something isn't going right.
And therefore certain neurochemicals are deployed
that signal the neural circuits that they have to change.
So let's talk about errors and making errors
and why and how that triggers the release of chemicals
that then allow us to not just learn the thing
that we're doing in the motor sense,
play the piano, dance, et cetera,
but it also creates an environment,
a milieu within the brain that allows us
to then go learn how to couple or uncouple
a particular emotion to an experience
or better language learning
or better mathematical learning.
Last episode, we discussed some of the basic principles
of neuroplasticity.
If you didn't hear that episode, no problem.
I'll just review it quickly,
which is that it's a falsehood that everything that we do
in experience changes our brain.
The brain changes when certain neurochemicals,
namely acetylcholine, epinephrine, and dopamine
are released in ways and in the specific times
that allow for neural circuits to be marked for change.
And then the change occurs later during sleep.
Basically, you need a certain cocktail of chemicals
released in the brain in order for a particular behavior
to reshape the way that our brain works.
So the question really is,
what allows those neurochemicals to be released?
And last episode, it talked all about focus.
If you haven't seen or heard that episode,
you might want to check it out
about some specific tools
and practices that can allow you to build up your capacity
for focus and release certain chemicals in that cocktail.
But today we're going to talk about the other chemicals
in the cocktail, in particular, dopamine.
And we're really going to center our discussion
around this issue of making errors
and why making errors is actually the signal
that tells the brain, okay, it's time to change
or more generally, it's time to pay attention to things
so that you change.
And I really want to distinguish this point really clearly
which is that I'm going to talk today a lot about motor
and vestibular, meaning balance programs
but not just for learning motor commands and balance,
but also for setting a stage
or a kind of condition in your brain
where you can go learn other things as well.
So let's talk about some classic experiments
that really nail down what's most important
in this discussion about plasticity.
I'd like to take a quick break
and acknowledge our sponsor, AG1.
By now, many of you have heard me say
that if I could take just one supplement,
that supplement would be AG1.
The reason for that is AG1 is the highest quality
and most complete
of the foundational nutritional supplements available.
What that means is that it contains
not just vitamins and minerals,
but also probiotics, prebiotics, and adaptogens
to cover any gaps you may have in your diet
and provide support for a demanding life.
For me, even if I eat mostly whole foods
and minimally processed foods,
which I do for most of my food intake,
it's very difficult for me to get enough fruits
and vegetables, vitamins and minerals, micronutrients,
and adaptogens from food alone.
For that reason, I've been taking AG1 daily since 2012.
When I do that, it clearly bolsters my energy, my immune system, and my gut microbiome.
These are all critical to brain function, mood, physical performance, and much more.
If you'd like to try AG1, you can go to drinkag1.com slash Huberman to claim their special offer.
Right now, they're giving away five free travel packs plus a year supply of vitamin D3K2.
Again, that's drinkag1.com slash Huberman
to claim that special offer.
So I mentioned last episode
and I'll just tell you right now, again,
the brain is incredibly plastic
from about birth until about age 25.
And then somewhere about 25,
it's not like the day after your 26th birthday,
plasticity closes, there's a kind of tapering off
of plasticity and you need different mechanisms to engage
plasticity as an adult.
Knowing how to tap into these plasticity mechanisms
is very powerful.
The simplest example is if I hear something off to my right,
I look to my right.
If I hear it on the left, I look to my left.
If I hear it right in front of me,
I keep looking right in front of me.
And that's because our maps of visual space
and our maps of auditory space
and our maps of motor space
are aligned to one another in perfect register.
It's an incredible feature of our nervous system.
It takes place in a structure called the superior colliculus,
although you don't need to know that name.
Superior colliculus has layers,
literally stacks of neurons, like in a sandwich,
where the zero point right in front of me,
or maybe 10 or 15 degrees off to my right,
or 10 or 15 degrees off to my left,
are aligned so that the auditory neurons,
the ones that care about sounds at 15 degrees to my right,
sit directly below the neurons that look at 15 degrees
to my right in my visual system.
And when I reach over to this direction,
there's a signal that's sent down through those layers
that says 15 degrees off to the right
is the direction to look, it's the direction to listen,
and it's the direction to move if I need to move.
So there's an alignment.
And this is really powerful.
And this is what allows us to move through space
and function in our lives in a really fluid way.
It's set up during development,
but there have been some important experiments
that have revealed that these maps are plastic,
meaning they can shift, they're subject to neuroplasticity.
And there are specific rules that allow us to shift them.
So here's the key experiment.
The key experiment was done by a colleague of mine,
who's now retired, but whose work is absolutely fundamental
in the field of neuroplasticity, Eric Knudsen.
The Knudsen lab and many of the Knudsen lab
scientific offspring showed that if one is to wear
prism glasses that shift the visual field,
that eventually there'll be a shift in the representation
of the auditory and motor maps too.
Now, what they initially did is they looked at young subjects
and what they did is they looked at young subjects
and what they did is they moved the visual world by making them wear prism glasses.
So that for instance, if my pen is out in front of me
at five degrees off center,
so just a little bit off center,
if you're listening to this,
this would be like just a little bit to my right.
But in these prism glasses,
I actually see that pen way over far on my right.
So it's actually here, but I see it over there
because I'm wearing prisms on my eyes.
What happens is in the first day or so,
you ask people or you ask animal subjects or whatever
to reach for this object and they reach to the wrong place
because they're seeing it where it isn't.
But what you find is that in young individuals,
within a day or two,
they start adjusting their motor behavior
in exactly the right way
so that they always reach to the correct location.
So they hear a sound at one location,
they see the object that ought to make that sound
at a different location,
and they somehow are able to adjust their motor behavior
to reach to the correct location.
It's incredible.
And what it tells us is that these maps
that are aligned to one another can move and shift.
And it happens best in young individuals.
If you do this in older individuals,
in most cases, it takes a very long time
for the maps to shift. And in some cases, they never shift. long time for the maps to shift.
And in some cases they never shift.
So this is a very experimental scenario,
but it's an important one to understand
because it really tamps down the fact
that we have the capacity to create dramatic shifts
in our representation of the outside world.
So how can we get plasticity as adult
that mimics the plasticity that we get
when we are juveniles?
Well, the Knudsen lab and other labs have looked at this
and it's really interesting.
The signal that generates the plasticity
is the making of errors.
It's the reaches and failures that signal
to the nervous system that this is not working.
And therefore the shifts start to take place.
And this is so fundamentally important
because I think most people understandably get frustrated.
Like they're trying to learn a piece on the piano
and they don't know they can't do it,
or they're trying to write a piece of code,
or they're trying to access some sort of motor behavior and they can't know they can't do it or they're trying to write a piece of code or they're trying to access some sort of motor behavior
and they can't do it.
And the frustration drives them crazy
and like, I can't do it, I can't do it.
When they don't realize that the errors themselves
are signaling to the brain and nervous system,
something's not working.
And of course the brain doesn't understand the words,
something isn't working.
The brain doesn't even understand frustration
as an emotional state. The brain understands't even understand frustration as an emotional state.
The brain understands the neurochemicals that are released,
namely epinephrine and acetylcholine,
but also, and we'll get into this,
the molecule dopamine when we start to approximate
the correct behavior just a little bit,
and we start getting a little bit right.
So what happens is when we make errors,
the nervous system starts releasing neurotransmitters
and neuromodulators that say,
we better change something in the circuitry.
And so errors are the basis for neuroplasticity
and for learning.
And I wish that this was more prominent out there.
I guess this is why I'm saying it.
And humans do not like this feeling of frustration
and making errors.
The few that do, do exceedingly well
in whatever pursuits they happen to be involved in.
The ones that don't, generally don't do well.
They generally don't learn much.
And if you think about it,
why would your nervous system ever change?
Why would it ever change?
Unless there was something to be afraid of,
something that made us feel awful
will signal that the nervous system needs to change
or there's an error in our performance.
So it turns out that the feedback of these errors,
the reaching to the wrong location
starts to release a number of things.
And now you've heard about them many times,
but this would be epinephrine, it increases alertness,
acetylcholine focus, because if acetylcholine is released,
it creates an opportunity to focus on the error margin,
the distance between what it is that you're doing
and what it is that you would like to do.
And then the nervous system starts to make changes
almost immediately in order to try
and get the behavior right.
And when you start getting it even a little bit right,
that third molecule comes online or is released,
which is dopamine,
which allows for the plastic changes to occur very fast.
Now, this is what all happens very naturally
in young brains, but in old brains,
it tends to be pretty slow, except for in two conditions.
So let me just pause and just say this.
If you are uncomfortable making errors and you get frustrated easily,
if you leverage that frustration toward drilling deeper
into the endeavor, you are setting yourself up
for a terrific set of plasticity mechanisms to engage.
But if you take that frustration
and you walk away from the endeavor,
you are essentially setting up plasticity
to rewire you according to what happens afterwards,
which is generally feeling pretty miserable.
So now you can kind of start to appreciate why it is
that continuing to drill into a process
to the point of frustration,
but then staying with that process for a little bit longer.
And I'll define exactly what I mean by a little bit,
is the most important thing for adult learning
as well as childhood learning,
but adult learning in particular.
Now the Knudsen lab did two very important sets
of experiments.
The first one, which showed that juveniles
can make these massive shifts in their map representations.
They get a lot of plasticity all at once.
It happens very fast in a period of just a couple of days.
In adults, it tends to be very slow
and most individuals never actually accomplished
the full map shift.
They don't get the plasticity.
Then what they did is they started making
the increment of change smaller.
So instead of shifting the world a huge amount
by putting prisms that shifted the visual world
all the way over to the right,
they did this incrementally.
So first they put on prisms that shifted it
just a little bit,
just like seven degrees, I believe was the exact number.
And then it was 14 degrees, and then it was 28 degrees.
And so what they found was that the adult nervous system
can tolerate smaller and smaller errors over time,
but that you can stack those errors
so that you can get a lot of plasticity.
Put simply, incremental learning as an adult
is absolutely essential.
You are not going to get massive shifts
in your representations of the outside world.
So how do you make small errors as opposed to big errors?
Well, the key is smaller bouts of focused learning
for smaller bits of information.
It's a mistake to try and learn a lot of information
in one learning bout as an adult.
Now, there is one way to get a lot of plasticity all at bout as an adult. Now there is one way to get a lot of plasticity
all at once as an adult.
There is that kind of Holy grail thing
of getting massive plasticity as you would
when you were a young person, but as an adult.
And the Knudsen lab revealed this
by setting a very serious contingency
on the learning.
What they did was they had a situation
where subjects had to find food that was displaced
in their visual world, again, by putting prisms
and they had to find the food and the food made a noise.
There was a noise set kind of the location of the food
through an array of speakers.
Basically, in order to eat at all, they needed plasticity.
And then what happened was remarkable.
What they observed is that the plasticity as an adult
can be as dramatic, as robust as it is in a young person
or in a young animal subject,
provided that there's a serious incentive
for the plasticity to occur.
And this is absolutely important to understand,
which is that how badly we need or want the plasticity
determines how fast that plasticity will arrive.
This means that the importance of something,
how important something is to us,
actually gates the rate of plasticity
and the magnitude of plasticity.
And this is why just passively going through most things,
going through the motions as we say,
or just getting our reps in quote unquote,
is not sufficient to get the nervous system to change.
If we actually have to accomplish something
in order to eat, or in order to get our ration of income,
we will reshape our nervous system very, very quickly.
And so I think that the studies that Knudsen did
showing the incremental learning
can create a huge degree of plasticity as an adult,
as well as when the contingency is very high,
meaning we need to eat or we need to make an income
or we need to do something that's vitally important for us
that plasticity can happen in these enormous leaps,
just like they can in adolescence and young adulthood.
That points to the fact that it has to be
a neurochemical system.
There has to be an underlying mechanism.
All the chemicals that we're about to talk about
are released from drug stores, if you will,
chemical stores that already reside in all of our brains.
And the key is how to tap into those stores.
And so we're going to next talk about
what are the specific behaviors
that liberate particular categories of chemicals
that allow us to make the most of incremental learning
and that set the stage for plasticity
that is similar enough or mimics
these high contingency states like the need to get food
or really create a sense of internal urgency,
chemical urgency, if you will.
I'd like to take a quick break
and thank one of our sponsors, David.
David makes a protein bar unlike any other.
It has 28 grams of protein,
only 150 calories and zero grams of sugar.
That's right, 28 grams of protein
and 75% of its calories come from protein.
These bars from David also taste amazing.
My favorite flavor is chocolate chip cookie dough.
But then again, I also like the chocolate fudge flavored one.
And I also like the cake flavored one.
Basically, I like all the flavors.
They're incredibly delicious.
For me personally, I strive to eat mostly whole foods.
However, when I'm in a rush or I'm away from home,
or I'm just looking for a quick afternoon snack,
I often find that I'm looking for a high quality protein source.
With David, I'm able to get 28 grams of protein
with the calories of a snack,
which makes it very easy to hit my protein goals
of one gram of protein per pound of body weight each day.
And it allows me to do that
without taking in excess calories.
I typically eat a David bar in the early afternoon
or even mid afternoon,
if I want to bridge that gap between lunch and dinner.
I like that it's a little bit sweet,
so it tastes like a tasty snack,
but it's also given me that 28 grams
of very high quality protein with just 150 calories.
If you would like to try David,
you can go to davidprotein.com slash Huberman.
Again, the link is davidprotein.com slash Huberman.
If you've heard previous episodes of this podcast,
you may have heard me talk about ultradian rhythms,
which are these 90 minute rhythms
that break up our 24 hour day.
They help break up our sleep into different cycles of sleep
like REM sleep and non-REM sleep and in waking states,
they help us, or I should say they break up our day
in ways that allow us to learn best
within 90 minute cycles, et cetera.
Today, we're really talking about how to tap into
plasticity through the completion of a task
or working towards something repetitively
and making errors.
The Ultradian cycle says that for the first
five to 10 minutes of doing that,
your mind is going to drift
and your focus will probably kick in
provided that you're visually,
you're restricting your visual world
to just the material in front of you,
something we talked about last episode,
somewhere around the 10 or 15 minute mark.
And then at best, you're probably going to get
about an hour of deliberate kind of tunnel vision
learning in there, your mind will drift.
And then toward the end of that,
what is now an hour and 10 or hour and 20 minute cycle,
you're going to, your brain will start to flicker in an hour.
You're trying your best to accomplish something
and you're failing.
You want to keep making errors for this period of time
that I'm saying will last anywhere
for about seven to 30 minutes.
It is exceedingly frustrating,
but that frustration, it liberates the chemical cues
that signal that plasticity needs to happen.
And it is the case that when we come back a day or two later
in a learning bout after a nap or a night or two
of deep rest, then what we find is that we can remember
certain things and the motor pathways work.
And we don't always get it perfectly,
but we get a lot of it right,
whereas we got it wrong before.
So that seven to 30 minute intense learning bout
specifically about making errors.
I want to really underscore that.
And it's not about, as I mentioned before,
coming up with some little hack or trick
or something of that sort.
It's really about trying to cue the nervous system
that something needs to change
because otherwise it simply won't change.
I think everyone could stand to enhance the rate of learning
by doing the following,
learn to attach dopamine in a subjective way
to this process of making errors,
because that's really combining two modes of plasticity
in ways that together can accelerate the plasticity.
In other words, making failures, failing repetitively,
provided we're engaged in a very specific set of behaviors
when we do it, as well as telling ourselves
that those failures are good for learning and good for us,
creates an outsized effect on the rate of plasticity.
It accelerates plasticity.
Now, some of you might be asking, and I get asked a lot,
well, how do I get dopamine to be released?
Can I just tell myself that something is good
when it's bad?
Well, actually, yes, believe it or not,
dopamine is one of these incredible molecules
that both can be released according to things
that are hardwired in us to release dopamine.
Again, things like food, sex, warmth when we're cold,
cool environments when we're too warm.
It's that kind of pleasure molecule overall,
but it's also highly subjective
what releases dopamine in one person versus the next.
So everyone releases dopamine in response
to those very basic kind of behaviors and activities,
but dopamine is also released according to what we
subjectively believe is good for us.
And that's what's so powerful about it.
In fact, a book that I highly recommend,
if you want to read more about dopamine,
is a book that frankly, I wish I had written.
It's such a wonderful book.
It's called The Molecule of More.
And it really talks about dopamine,
not just as a molecule associated with reward,
but a molecule associated with motivation and pursuit
and just how subjectively controlled dopamine can be.
So make lots of errors,
tell yourself that those errors are important and good
for your overall learning goals.
So learn to attach dopamine,
meaning release dopamine in your brain
when you start to make errors.
Once you're attaching dopamine to this process
of making errors, then I start getting lots of questions
that really are the right questions,
which are, you know, how often should I do this?
And when should I be doing this?
And at what time?
Well, I've talked a little bit about this
in previous episodes, but as long as we're now kind of
into the nitty gritty of tools and application,
each of us have some natural times throughout the day
when we are going to be much better
at tolerating these errors and much more focused
on what it is that we're trying to do.
Last episode was about focus, but chances are
that you can't focus as well at 4 p.m. as you can at 10 a.m.
It differs for everybody depending on when you're sleeping
and your kind of natural chemistry and rhythms,
but find the time or times of day
when you naturally have the highest mental acuity.
And that's really when you wanna engage
in these learning bouts.
And then get to the point where you're making errors
and then keep making errors for seven to 30 minutes.
Just keep making those errors and drill through it.
And you're almost seeking frustration.
And if you can find some pleasure in the frustration,
yes, that is a state that exists.
You have created the optimal neurochemical milieu
for learning that thing.
But then here's the beauty of it.
You also have created the optimal milieu
for learning other things afterward.
At least for an hour or so, I would say,
you're going to be in a state of heightened learning.
Again, these aren't gimmicks,
these tap into these basic mechanisms of plasticity.
And the three that I'd like to talk about next
are balance, meaning the vestibular system,
as well as the two sides of what I call limbic friction
or autonomic arousal.
And if none of that makes sense,
I'm going to put a fine point on each one of those
and what it is and why it works
for opening up neuroplasticity.
I'd like to take a quick break
and thank our sponsor, BetterHelp.
BetterHelp offers professional therapy
with a licensed therapist carried out entirely online.
I've been doing weekly therapy for well over 30 years.
Initially, I didn't have a choice.
It was a condition of being allowed to stay in school,
but pretty soon I realized that therapy
is an extremely important component to one's overall health.
In fact, I consider doing regular therapy
just as important as getting regular exercise.
Now there are essentially three things
that Great Therapy provides.
First of all, it provides a good rapport with somebody that you can trust and talk to about essentially all things that great therapy provides. First of all, it provides a good rapport
with somebody that you can trust and talk to
about essentially all issues that you want to.
Second of all, great therapy provides support
in the form of emotional support
or simply directed guidance,
what to do or what not to do in given areas of your life.
And third, expert therapy can provide you useful insights
that you would not have been able to arrive at on your own.
BetterHelp makes it very easy to find an expert therapist
who you really resonate with
and that can provide you the benefits I just mentioned
that come with effective therapy.
If you'd like to try BetterHelp,
go to betterhelp.com slash Huberman
to get 10% off your first month.
Again, that's betterhelp.com slash Huberman.
Let's talk about limbic friction.
Limbic friction, I realize is not something
you're going to find in any of the textbooks,
but it is an important principle
that captures a lot of information that is in textbooks,
both neurobiology and psychology,
and it has some really important implications.
Limbic friction is my attempt to give a name to something
that is more nuanced and mechanistic than stress.
Because typically when we hear about stress,
we think of heart rate, heart beat going too fast,
breathing too fast, sweating,
and not being in a state that we want,
we're too alert and we want to be more calm.
And indeed, that's one condition
in which we have limbic friction,
meaning our limbic system is taking control
of a number of different aspects of our autonomic
or automatic biology.
And we are struggling to control that
through what we call top-down mechanisms.
We're trying to calm down in order to reduce
that level of arousal.
We're all familiar with this.
It's called the stress response.
However, there's another aspect of stress
that's just as important, which is when we're tired
and we're fatigued and we need to engage,
we need to be more alert than we are.
And so what I call limbic friction is really designed
to describe the fact that when our autonomic nervous system
isn't where we want it, meaning we're trying to be more alert or we're trying to be less
alert, both of those feel stressful to people.
But the reason I'm bringing this up is that in order to access neuroplasticity, you need
these components of focus.
You need the component of attaching subjective reward.
You need to make errors, all this stuff. And a lot of people find it difficult
to just get into the overall state to access those things.
Here's the beauty of it.
If you are too alert, meaning you're too anxious
and you want to calm down in order to learn better,
there are things that you can do.
The two that I've spoken about previously
on various podcasts, and I'll just review them
really quickly, are the double inhale exhale.
So inhaling twice through the nose
and exhaling once through the mouth.
This is what's called a physiological sigh.
It offloads carbon dioxide from the lungs.
The other thing is starting to remove your tunnel vision.
When you use tunnel vision, you're very focused
that epinephrine is released by dilating your field of gaze,
so-called panoramic vision.
But the other side of limbic friction is important too.
If you are too tired and you can't focus,
well, then it's going to be impossible
to even get to the starting line, so to speak,
for engaging in neuroplasticity
through incremental learning, et cetera.
So in that case, there are other methods
that you can do to wake yourself up.
The best thing you should do is get a good night's sleep,
but that's not always possible
or use an NSDR non-sleep deep rest protocol.
But if you've already done those things
or you're simply exhausted for whatever other reason,
then there are other things that I often get asked about.
Like sure, a cup of coffee or super oxygenation breathing,
which means inhaling more than exhaling on average
in a breathing bout.
Now we're sort of getting toward the realm
of like how you could trick your nervous system
into waking up.
And if you bring more oxygen in
by making your inhales deeper and longer,
you will become more alert.
You'll start to actually deploy norepinephrine
if you breathe very fast.
So there are things that you can do
to move up or down this so-called autonomic arousal arc.
And what you want to ask
before you undergo
any learning bout is how much limbic friction
am I experiencing?
Am I too alert and I want to be calmer?
Or am I too calm and too sleepy
and I want to be more alert?
You're going to need to engage in behaviors
that bring you to the starting line in order to learn.
There are other things that you can do
in order to then learn better and faster
besides incremental learning
and those center on the vestibular system.
Why the vestibular system to access neuroplasticity?
Well, we have a hardwired system for balance.
And here's how it works in as simple terms
as I can possibly come up with.
As we move through space, or even if we're stationary,
your brain doesn't really know where your body is,
except when through that proprioceptive feedback.
The main way it knows is through three planes of movement
that we call pitch, which is like nodding.
So if I nod like this, that's pitch.
Then there's yaw, which is like shaking my head no.
And then there's roll from side to side,
like when a puppy looks at you like, that kind of thing.
Okay, so pitch, yaw and roll.
Our ears have two main roles.
One is to hear, right?
To perceive sound waves
or taking sound waves for perception, so-called hearing.
And the other is balance, a vestibular function.
So sitting in our ears are these semi-circular canals
and they're these little tubes where these little stones,
they're actually little bits of calcium,
roll back and forth like little marbles.
When we roll this way, they roll this way.
When we pitch, when we go from side to side,
there's some that sit flat like this and they go
like marbles inside of a hula hoop. And then we have roll, there's some that sit flat like this and they go like marbles inside of a hula hoop.
And then we have roll.
There's some that are kind of at 45 degrees to those
and it's kind of pitch, yaw and roll.
So you're okay, great.
That sends signals to the rest of our brain and body
that tell us how to compensate
for shifts relative to gravity.
I say, okay, well, I thought we were talking
about plasticity, but this is where it gets really,
really cool.
Errors in vestibular motor sensory experience,
meaning when we are off balance
and we have to compensate by looking at,
thinking about or responding to the world differently,
cause an area of our brain called the cerebellum,
it actually means mini brain,
it looks like a little mini brain
like tucked below our cortex in the back,
cause the cerebellum to signal some of these
deeper brain centers that release dopamine,
norepinephrine and acetylcholine.
And that's because these circuits in the inner ear, etc.
And the cerebellum, they were designed to recalibrate our motor movements
when our relationship to gravity changes,
something fundamental to survival.
We can't afford to be falling down all the time
or missing things that we grab for
or running in the wrong direction
when something is pursuing us.
These are hardwired circuits
that tap right into these chemical pathways.
And those chemical pathways are the gates to plasticity.
So I really want to spell this out clearly
because I've given a lot of information today.
The first thing is how are you arriving
to the learning bout?
You need to make sure your level
of autonomic arousal is correct.
The ideal state is going to be clear, calm and focused,
maybe a little bit more on the arousal level,
like heightened arousal.
So understand limbic friction,
understand that you can be too tired,
in which case you're going to need to get yourself
a little more alert,
or you can be too alert
and you're going to need to get yourself calmer.
So the first gate is to arrive at learning
at the appropriate level of autonomic arousal.
Clear and focused is best,
but don't obsess over being right there.
It's okay to be a little anxious or a little bit tired.
Then you want to make errors.
We talked about that.
And this vestibular motor sensory relationship
is absolutely key if you want to get heightened
or accelerated plasticity.
And we talked about another feature
which is setting a contingency.
If there's a reason, an important reason for you
to actually learn, even if you're making failures
the learning will be accelerated.
So there's really four things
that you really need to do for plasticity as an adult.
And I would say that these also apply to young people.
And there's an interesting kind of thought experiment
there as well, which is if you look at children,
they are moving a lot in different dimensions.
Whatever sport the kids are playing,
or even if they don't play a sport,
they tend to move in a lot of different relationships
to gravity, more dimensionality to their movements,
I should say, than adult.
As we age, we get less good at engaging in neuroplasticity.
Part of that is because as we get older,
we tend to get more linear and more regular
about the specific kinds of movements.
So you sort of have to wonder whether or not
the lack of plasticity or the reduced plasticity
in older individuals, which includes me,
would reflect the fact that those chemicals
aren't being deployed because we're not engaging
in certain behaviors as opposed to we can't engage
in the behaviors because the chemicals aren't being deployed.
So I want to make sure that I underscore the fact
that this vestibular thing that I've been describing
is a way to really accentuate plasticity.
It's tapping into an inborn biological mechanism
where the cerebellum has outputs
to these deep brain nuclei associated
with dopamine, acetylcholine, and norepinephrine.
That's kind of an amplifier on plasticity
as is high contingency.
If you really need to learn conversational French
to save your relationship,
the chances are you're going to learn it.
Now there are limits to this, of course, too. If someone puts a gun to my head and says, learn conversational French to save your relationship, the chances are you're going to learn it. Now there are limits to this, of course, too.
If someone puts a gun to my head and says,
learn conversational French in the next 120 seconds,
I think we would probably be my only response
because I can't stuff in all the knowledge all at once.
I mean, I think that's the dream of brain machine interface
that one will be able to download a chip
into their hippocampus or cortex
or some other brain structure that would allow them
to download conversational French.
And someday we may get to that.
And so my overall goal here in this episode
and with this podcast is to give you some understanding
of the mechanisms and the insights
into the underlying biology that allow you to tailor
what these
kind of foundational mechanisms are
to suit your particular learning needs.
So I very much thank you for your time and attention.
I know it's a lot of information
and it takes a bit of focus and attention
and certainly will trigger plasticity
to learn all this information.
I want to encourage you and just remind you
that you don't have to grasp it all at once,
that it is here archived,
and that if you want to return to the information,
it will still be here.
And that I most of all,
really appreciate your interest in science.
Thank you so much.
Thank you.
Thank you.
Thank you.
Thank you.
Thank you.