Huberman Lab - Essentials: Understand & Improve Memory Using Science-Based Tools
Episode Date: April 16, 2026In this Huberman Lab Essentials episode, I explain how memories are formed and how key neurochemicals, such as adrenaline, can be leveraged to enhance memory formation. I also share science-based prot...ocols to enhance learning, strengthen memory recall and reduce the number of repetitions needed to retain new information. In addition, I discuss how exercise supports cognitive function and memory and explore unique memory phenomena such as déjà vu. Read the show notes at hubermanlab.com. Thank you to our sponsors AG1: https://drinkag1.com/huberman Eight Sleep: https://eightsleep.com/huberman LMNT: https://drinklmnt.com/huberman Timestamps (00:00:00) Memory (00:00:21) Sensory Stimuli & Memory Bias (00:01:54) Associations & Memory; Tool: Repetition (00:05:00) Sponsor: Eight Sleep (00:06:18) Stress, Adrenaline & Strengthening Memories (00:11:10) Caffeine & Stimulants, Tool: Timing to Enhance Learning & Memory (00:14:39) Tool: Naps & Sleep for Learning & Memory (00:16:56) Sponsor: AG1 (00:18:19) Increase Adrenaline to Enhance Learning & Memory, Chronic Stress (00:21:56) Adrenaline Boosts Memory: Centuries-Old Practice (00:24:03) Tool: Cardiovascular Exercise & Brain Health, Neurogenesis (00:26:11) Exercise, Osteocalcin, Hippocampus & Memory (00:29:37) Sponsor: LMNT (00:31:09) Tool: Photographs, Mental Snapshots & Improved Memory (00:34:08) Déjà Vu (00:36:22) Tool: Brief Meditation Practice to Enhance Memory (00:38:38) Recap Disclaimer & Disclosures Learn more about your ad choices. Visit megaphone.fm/adchoices
Transcript
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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.
I'm Andrew Huberman and I'm a professor
of neurobiology and ophthalmology
at Stanford School of Medicine.
Today we are discussing memory, in particular,
how to improve your memory.
We are constantly being bombarded with physical stimuli,
patterns of touch on our skin, light to our eyes,
light to our skin for that matter, smell,
tells, tastes, and sound waves.
Each one of and all of those sensory stimuli
are converted into electricity and chemical signals
by your so-called nervous system, your brain, your spinal cord,
and all their connections with the organs of the body,
and all the connections of your organs of the body,
back to your brain and spinal cord.
For instance, if you can hear me speaking right now,
you are perceiving my voice,
but you are also, most likely,
neglecting the feeling of the contact of your skin
with whichever surface you happen to be sitting or standing on.
It is only by perceiving a subset,
a small fraction of the sensory events in our environment,
that we can make sense of the world around us.
Otherwise, we would just be overwhelmed
with all the things that are happening
in any one given moment.
Now, memory is simply a bias
in which perceptions will be replayed again in the future.
Now, this might seem immensely simple,
but it raises this really interesting question,
which we talked about before,
which is why do we remember certain things
and not others?
Because according to what I've just said,
as you go through life,
you're experiencing things all the time.
You're constantly being bombarded with sensory stimuli.
Some of those sensory stimuli you perceive,
and only some of those perceptions get stamped down as memories.
Today I'm gonna teach you how certain things
get stamped down as memories.
And I'm going to teach you how to leverage that process
in order to remember the information that you want far better.
Each individual thing that we remember
or that we want to remember
is linked to something by either a close,
a medium, or a very distant association.
This turns out to be immensely important.
I know many of you will read or will encounter programs
that are designed to help you enhance your memory.
You know, you have these phenoms that can remember
50 names in a room full of people
or they can remember a bunch of names of novel objects
or maybe even in different languages.
And oftentimes that's done by association.
So people will come up with little mental tricks
to, you know,
either link the sound of a word or the meaning of a word
in some way that's meaningful for them
and will enhance their memory.
That can be done and is impressive when we see it.
And for those of you can do that, congratulations.
Most of us can't do that,
or at least it requires a lot of effort and training.
However, there are things that we can do
that leverage the natural biology of our nervous system
to enhance learning and memory
of particular perceptions and particular information.
So let's talk about tools for enhancing memory.
Now there's one tool,
that it's absolutely clear works.
And that's repetition.
The more often that you perform something
or that you recite something,
the more likely you are to remember it in the future.
And while that might seem obvious,
it's worth thinking about what's happening
when you repeat something,
but when I say what's happening,
I mean at the neural level.
What's happening is that you're encouraging
the firing of particular chains of neurons
that reside in a particular circuit, right?
So a particular sequence of neurons playing,
Neuron A, B, C, D played in that particular sequence
over and over and over again.
And with more repetitions, you get more strengthening
of those nerve connections.
The problem for most people is that they either
don't have the patients, they don't have the time,
and sometimes they literally don't have the time
because they've got a deadline on something
that they're trying to remember and learn.
Or they simply would like to be able to remember things better
in general, remember them more quickly.
This process of accelerating repetition-based learning,
so that your learning curve doesn't go from having
to perform something a thousand times
and then gradually over time, it's 1,750 times a day,
500 times a day, 300 times a day,
and down to no repetitions, right?
You can just perform that thing the first time and every time.
Well, there is a way to shift that curve
so that you can essentially establish stronger connections
between the neurons that are involved
in generating that memory or behavior more quickly.
How do you do that?
Well, in order to answer that,
we have to look at the beautiful work
of James McGaugh and Larry Cahill.
James McGaw and Larry Cahill did a number of experiments
over several decades really that really established
what's required to get better at remembering things
and to do so very quickly.
They evaluated the capacity for stress
and for particular neurochemicals associated with stress
to improve our ability to learn information,
not just information that is emotional,
but information of all kinds.
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So I'm going to describe some experiments done in animal models just very briefly, and then experiments done on human subjects.
If you take a rat or a mouse and put it in an arena
where at one location the animal receives an electrical shock,
and then you come back the next day,
you remove the shock evoking device,
and you let the animal move around that arena,
that animal will quite understandably avoid the location
where it was shock, so-called conditioned place aversion.
That effect of avoiding that particular location
occurs in one trial.
That's a good example of one trial learning.
So somehow the animal knows that it was shocked at that location.
It remembers that it is a hippocampal dependent learning.
They remember it after the first time and every time.
Unless you are to block the release of certain chemicals
in the brain and body and the chemicals I'm referring to
are epinephrine, adrenaline, and to some extent, cortisol.
Now we know that the effect of getting one trial learning
somehow involves epinephrine, at least in this particular experience,
experimental scenario because if researchers do the exact same experiment,
and they have done the exact same experiment,
but they introduce a pharmacological blocker of epinephrine
so that epinephrine is released in response to the shock,
but it cannot actually bind to its receptors
and have all of its biological effects,
well then the animal is perfectly happy
to tread back into the area where it received the shock.
It's almost as if it didn't know,
or we have to assume,
they didn't remember that it received
shock at that location.
So it all seems pretty obvious when you hear it.
Something bad happens in a location,
you don't go back to that location.
But it turns out that the opposite is also true,
meaning for something called condition place preference,
you can take an animal, put it into an arena,
feed it or reward it somehow at one location,
take the animal out, come back the next day.
No food is introduced, but it'll go back to the location
where it received the food.
Or you can do any variant of this.
You can make the arena a little bit chilly
and provide warmth at that location,
or you can take
a male animal, it turns out male rats and mice
will mate at any point or a female animal
that's at the particular so-called receptive phase
of her mating cycle and give them an opportunity
to mate at a given location, they'll go back
to that location and wait and wait.
This is perhaps why people go back to the same bar,
seat at the bar or the same restaurant
and wait because of the one time
they, you know, things worked out for them,
whatever the context was.
Condition place preference,
as with condition place avoidance
depends on the release of adrenaline, right?
It's not just about,
stress it's about a heightened emotional state in the brain and body okay this is
really important it's not just about stress you can get one trial learning for
positive events condition place preference and you can get one trial learning for
negative events this turns out all to be true for humans as well we know that
because McGahn Cahill did experiments where they gave people a boring paragraph
to read and only a boring paragraph to read but one group of subjects
was asked to read the paragraph
and then to place their arm into very, very cold water.
In fact, it was ice water.
We know that placing one's arm into ice water,
especially if it's up to the shoulder or near to it,
evokes the release of adrenaline in the body.
It's not an enormous release, but it's a significant increase.
And yes, they measured adrenaline release.
In some cases, they also measured for things like cortisol, et cetera.
And what they found is that if one evokes the release
of adrenaline through this arm into ice water approach,
the information that they read previously,
just a few minutes before was remembered.
It was retained as well as emotionally intense information.
But keep in mind, the information that they read
was not interesting at all,
or at least it wasn't emotionally laden.
This had to be the effect of adrenaline released
into the brain and body because if they blocked the release
or the function of adrenaline in the brain,
and or body, they could block this effect.
This is absolutely important in terms of thinking
about tools to improve your memory.
It is the presence of high adrenaline,
high amounts of nor epinephrine and epinephrine
that allows a memory to be stamped down quickly
and far in a way different than the idea
that we remember things because they're important to us
or because they evoke emotion.
That's true, but the real reason,
the neurochemical
reason, the mechanism behind all that
is neurochemicals have the ability
to strengthen neural connections
by making them active just once.
There's something truly magic about that neurochemical cocktail
that removes the need for repetition.
Okay, so let's apply this knowledge.
Let's establish a scientifically grounded set of tools,
meaning tools that take into account
the identity of the neurochemicals
that are important for enhancing learning
and the timing of the release of those
in order to enhance learning.
Caffeine in the form of coffee or Yerba Mata
or any other form of caffeine does create a sense of alertness
in our brain and body.
So my typical way of approaching learning and memory
would be to drink some caffeine and then focus really hard
on whatever it is that I'm trying to learn,
trying to eliminate distractions, and then hope, hope, hope,
or try, try, try to remember that information
as best as I could.
Frankly, I felt like it was working pretty well for me.
And typically, if I leveraged other forms
of pharmacology in order to enhance
learning in memory, things like alpha GPC or phosphatidyl syrin.
I would do that by taking those things
before I sat down to learn a particular set of information
or before I went off to learn a particular physical skill.
For those of you out there listening to this,
you're probably thinking, well, okay,
the results of McGaugh and C. Hill pointed to the fact
that having adrenaline released after learning something,
enhanced learning of that thing.
But a lot of these things,
like caffeine or alpha GPC can increase epinephrine
and adrenaline or dopamine or other molecules
in the brain and body that can enhance memory
for a long period of time.
So it makes sense to take it first or even during learning
and then allow that increase to occur
and the increase will occur over a long period of time
and will enhance learning and memory.
While that is partially true,
it is not entirely true and it turns out it's not optimal.
And it turns out that the best time window
to evoke the release of these chemicals,
if the goal is to enhance learning and memory of the material
is either immediately after or just a few minutes,
five, ten, maybe 15 minutes after you're repeating that information.
You're trying to learn that information.
Again, this could be cognitive information
or this could be a physical skill.
Now, this really spits in the face of the way
that most of us approach learning and memory.
Most of us, if we use stimulants like caffeine,
or alpha GPC, we're taking those before or during
an attempt to learn, not afterwards.
If you're using those compounds in order to enhance learning and memory,
well then I encourage you to try and take them
either late in the learning episode
or immediately after the learning episode.
Now given everything I've told you up until now,
why would I say late in the learning episode
or immediately after it?
Well, when you ingest something by drinking it
or you take it in capsule form,
there's a period of time before that gets absorbed
into the body in different substances,
such as caffeine,
and alpha GPC, et cetera, are absorbed from the gut
and into the bloodstream and reach the brain
and trigger these effects in the brain and body
at different rates.
So it's not instantaneous.
Some have effects within minutes, others within tens of minutes,
and so on.
It's really going to depend on the pharmacology of those things,
and it's also going to depend on whether or not you have food in your gut,
what else you happen to have circulating in your bloodstream, et cetera.
But at a very basic level, we can confidently say
that there are not one, not dozens,
but as I mentioned before, hundreds
of studies in animals and in humans that point
to the fact that triggering the increase of adrenaline
late in learning or immediately after learning
is going to be most beneficial if your goal
is to retain that information for some period of time
and to reduce the number of repetitions required
in order to learn that information.
Now, I want to acknowledge that on previous episodes
of this podcast, I've talked a lot about things
like non-sleep deep rest and naps and sleep
as vital to the learning process.
And I want to emphasize that none of that information
has changed, right?
I don't look at any of that information
differently as the consequence of what I'm talking about today.
It is still true that the strengthening of connections in the brain,
the literal neuroplasticity, the changing of the circuits occurs during deep sleep and
non-sleep deep rest.
And it is also true, and I've mentioned these results earlier, that two papers were published
in cell reports, cell press journal, excellent journal over the last few years, showing that
brief naps of about 20 to up to 90 minutes in some period of time after an attempt to learn
it can enhance the rate of learning and memory.
That still can be performed,
but it can be performed some hours later,
even an hour later.
It can be performed two hours later or four hours later.
Remember, it's in these naps and in deep sleep
that the actual reconfiguration of the neural circuits occurs,
the strengthening of those neural circuits occurs.
It is not the case that you need to finish about
of learning and drop immediately into a nap or sleep.
Some people might do that,
but if you're really trying to optimize
and enhance and improve
your memory, the data from McGaugh and Cahill
and many other laboratories that stemmed out
from their initial work really point to the fact
that the ideal protocol would be focused
on the thing you're trying to learn very intensely,
still try and get excellent sleep.
Again, fundamentally important for mental health,
physical health and performance,
and we can now extend from performance to saying,
including learning and memory.
Nap if it doesn't interrupt your nighttime sleep,
naps of anywhere from 10 to 90 minutes
or non-sleep deep rest protocols
will enhance learning and memory,
but we can now add to that that spiking adrenaline,
provided it can be done in a safe way,
is going to reduce the number of repetitions required to learn.
And that should be done at the very tail end
or immediately after a learning bout,
which is compatible with all the other protocols that I mentioned.
And the reason I'm revisiting the stuff about sleep
and non-sleep deep rest is I think that some people got the impression
that they need to do that immediately after learning.
And today I'm saying to the contrary.
Immediately after learning,
need to go into a heightened state of emotionality and alertness.
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Now, it's vitally important to point out that you do not need pharmacology.
You don't need caffeine.
You don't need alpha-GPC.
You don't need any pharmacologic substance to spike adrenaline unless that's something that
you already are doing or that you can do safely or that you know that you can do safely.
So if you're somebody who's not used to drinking caffeine and you suddenly drink for espresso
after trying to learn something, you are going to have a severe increase in alertness and
probably even anxiety.
If you're panic attack prone,
please don't start taking stimulants
in order to learn things better.
You could take a cold shower.
You could do an ice bath
or get into a cold circulating bath
in order to evoke epinephrine and dopamine release.
You could go out for a hard run.
You could do any number of things
that would increase adrenaline in your body.
Which things you choose is up to you.
But the overall takeaway is that anything
that increases adrenaline
will increase learning and memory
and will reduce the number of repetitions required
to learn something.
And as a cautionary note,
don't think that you can push this entire system
to the extreme over and over again,
or chronically as we say, and get away with it.
In other words, you're not gonna be able to take
a alpha GPC and a double espresso,
do your focus bout of work, cognitive or physical work,
and then spike adrenaline again afterwards
and remember that stuff even better, right?
I'm not encouraging you.
In fact, I'm discouraging you,
you from chronically increasing adrenaline
both during and after a given bout of work
if the goal is to learn.
Why do I say that?
Well, work from McGa and Cahill and others has shown
that it's not the absolute amount of adrenaline
that you release in your brain and body
that matters for enhancing memory.
It's the amount of adrenaline that you release
relative to the amount of adrenaline
that was in your system.
just prior, in particular in the hour or two prior.
So again, it's the delta, as we say, it's the difference.
So if you're gonna chronically increase adrenaline,
you're not gonna learn as well.
The real key is to have adrenaline modestly low,
perhaps even just as much as you need
in order to be able to focus on something,
pay attention to it, and then spike it afterwards.
This is immensely important because,
well, much of what we're talking about
is actually a form of inducing
a neurochemical acute stress, meaning a brief,
and rapid onset of stress,
well, chronic stress,
the chronic elevation of epinephrine and cortisol
is actually detrimental to learning.
And there's an entire category of literature,
mainly from the work of the great
and sadly the late Bruce McEwen from the Rockefeller University
and some of his scientific offspring,
like the great Robert Sapolsky, showing that chronic stress,
chronic elevation of epinephrine actually inhibits learning
in memory and also can inhibit immune system
function, whereas acute, sharp increases in adrenaline
and cortisol actually can enhance learning
and indeed can enhance the immune system.
So if you really want to leverage this information,
you might consider getting your brain and body
into a very calm and yet alert state,
so a high attentional state that will allow you
to focus on what it is that you're trying to learn.
We know focus is vital for encoding information
and for triggering neuroplasticity,
but remaining calm throughout that time
and then afterwards spiking adrenaline
and allowing adrenaline to have these incredible effects
on reducing the number of repetitions required to learn.
So if you're like me, you're learning about this information,
this beautiful work of McGaugh and Cahill and others,
and thinking, wow, I should perhaps consider
spiking my adrenaline in one form or another
at the tail end or immediately following
an attempt to learn something.
And yet we are not the first to have this conversation,
nor were McGaugh and Cahill
or any other researchers that I've ever,
discussed today, the first to start using this technique.
In fact, there is a beautiful review that was published in the journal Neuron, Cell Press
Journal, Excellent Journal, called Mechanisms of Memory Under Stress.
And I just want to read to you the first opening paragraph of this review.
So here I'm reading and I quote, in medieval times communities through young children in the
river when they wanted them to remember important events.
They believe that throwing a child in the water after witnessing historic proceedings would
leave a lifelong memory for the events in the child.
Believe it or not, this is true.
This is a practice that somehow people arrived at.
I don't know if they were aware of what adrenaline was,
probably not, but somehow in medieval times,
it was understood that spiking adrenaline
or creating a robust emotional experience
after an experience that one hoped a child would learn
would encourage the child's nervous system,
and they even know what a nervous system was,
but would encourage the brain and body of that child
to remember those particular events.
Very counterintuitive, if you ask me.
I would have thought that the kid would remember
only being thrown into the river.
My guess is that they remember that,
but that the idea here anyway is that they also remember
the things that preceded being thrown into the river.
So both interesting and amusing
and somewhat, I should say, thought stimulating really,
that this is a practice that has been going
on for many hundreds of years.
And we are not the first to start thinking about using
cold water as an adrenaline stimulus,
nor are we the first to start thinking about using
cold water induced adrenaline as a way
to enhance learning and memory.
This has been happening since medieval times.
So now I'd like to talk about other tools
that you can leverage that have been shown
in quality peer reviewed studies to enhance learning and memory.
And perhaps one of the most potent of those tools
is exercise.
There are numerous studies on this in
in both animal models and fortunately now also in humans,
thanks to the beautiful work of people like Wendy Suzuki
from New York University.
If you recall earlier, I mentioned that learning and memory
almost always involves the strengthening
of particular synapses and neural circuits in the brain.
There is one exception, however,
and we now have both animal data and some human data
to support the fact that cardiovascular exercise
seems to increase what we call dentate gyrus neurogenesis.
Neurogenesis is the creation of new neurons.
The dentate gyrus is a sub-region of the hippocampus
that's involved in learning and memory of particular kinds.
It's very clear that getting a minimum of 180
to 200 minutes of so-called zone two cardiovascular exercise,
so this is cardiovascular exercise that can be performed
at a pretty steady state,
we believe that it is indirectly,
I should say indirectly through enhancements
in cardiovascular fitness,
that there are improvements in hippocampal dentate gyrus,
neurogenesis.
What does that mean?
the improvements in cardiovascular function
are indirectly impacting the ability
of the dentate gyres to create these new neurons.
To my knowledge, there's no direct relationship
between exercise and stimulating
the production of new neurons in the brain.
It seems that it's the improvements in blood flow
that also relate to improvements in things like lymphatic flow,
the circulation of lymph fluid within the brain
that are enhancing neurogenesis
and that neurogenesis, it appears, is important.
Now, in fairness to the landscape of neuroscience
and my colleagues at Stanford and elsewhere,
there is a lot of debate as to whether or not
there is much, if any, neurogenesis in the adult human brain.
But regardless, I think the data are quite clear
that the 180 to 200 minutes minimum
of cardiovascular exercise is going to be important
for other health metrics.
Now, it is clear that exercise can impact learning
and memory through other non-neurodosephemy,
non-new neuron type mechanisms.
And one of the more exciting one that has been studied over the years
is this notion of hormones from bone traveling in the bloodstream
to the brain and enhancing the function of the hippocampus.
Yes, indeed, your bones make hormones.
We call these endocrine effects, so they're effectively acting as hormones.
And one such chemical is something called osteocalcin.
Now, these findings arrive to us through various labs,
but one of the more important labs for sake of this
discussion today is the laboratory of Eric Kendall
at Columbia Medical School.
His laboratory has studied the effects of exercise
on hippocampal function in memory,
and other laboratories have done that as well.
And what they found is that cardiovascular exercise
and perhaps other forms of exercise too,
but mainly cardiovascular exercise,
creates the release of osteocalcin from the bones
that travels to the brain and to sub-regions
of the hippocampus and encourages the electrical
activity and the formation and maintenance of connections within the hippocampus and keeps the hippocampus
functioning well in order to lay down new memories. So much of our brain real estate is devoted to
movement that it's been hypothesized for more than a half century, but especially in recent years
as we've learned more about the function of the brain at a really detailed circuit level,
that the relationship between the brain and body and the maintenance and perhaps even the
improvement of neural circuitry in the brain
depends on our body movements
and the signal from the body that our brain is still moving.
The fact that osteocalcin is released from bone
and in particular can be released
in response to load bearing exercise.
So this would be running.
Again, weight lifting hasn't been tested directly
but one would imagine anything involves jumping
and landing or weight lifting or body weight movements
and things of that sort.
That's a signal to release osteocathing
and we know that signal occurs,
that is directly reflective of the fact
that the body was moving and moving in particular ways.
In fact, you could imagine that big bones, like your femur,
are going to release more osteocalcin
or be in a position to release more osteocalcin
than five movements, five movements like the movements of the digits.
And this idea that the body is constantly signaling to the brain
about the status of the body
and the varying needs of the brain
to update its brain circuitry,
is a really attractive idea that fits entirely
with the biology of exercise, osteocalcin,
and hippocampal function.
Now, I certainly don't wanna give the message
that just moving, just exercise is sufficient
to keep the neural architecture of your brain
healthy, young, and able to learn.
While that might be true,
it's also important to actually engage
in attempts to learn new material,
either physical material, so new types of movements
and skills and or new types of cognitive information,
languages, mathematics, history, current events,
all sorts of things that involve your brain.
Nonetheless, it's clear that physical movement
and cognitive ability and the potential
to enhance cognitive ability
and the ability to learn new physical skills
are intimately connected.
And osteocalcin appears to be at least one way
in which that brain-body relationship
is established and maintained.
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Proper hydration is critical for optimal brain and body function.
Even a slight degree of dehydration can diminish cognitive and physical performance.
It's also important that you get adequate electrolytes.
The electrolytes, sodium, magnesium, and potassium are vital for functioning of all the cells in your body,
especially your neurons or your nerve cells.
Drinking element dissolved in water makes it very easy to ensure that you're getting adequate hydration
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To make sure that I'm getting proper amounts of hydration and electrolytes,
I dissolve one packet of element in about 16 to 32 ounces of water when I first wake up in the morning,
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I'll also drink Element dissolved in water during any kind of physical exercise that I'm doing,
especially on hot days when I'm sweating a lot and losing water and electrolytes.
Element has a bunch of great tasting flavors.
I love the raspberry. I love the citrus flavor.
Right now, Element has a limited edition lemonade flavor that is absolutely delicious.
I hate to say that I love one more than all the others,
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Again, I can't pick just one flavor.
I love them all.
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spelled drinklmn t.com slash Huberman
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Again, that's drink element.com slash Huberman to claim a free sample pack.
Next, I'm going to tell you about a study which
points out the immense value of visual images
for laying down memories.
And you can leverage this information,
and this involves both the taking of photographs,
something that's actually quite easily done these days
with your phone, as well as your ability
to take mental photographs by literally snapping your eyelids shut.
So I just briefly wanna describe this paper
because it provides a tool that you can leverage
in your attempt to learn and remember things better.
The title of this paper is photographic memory,
the effects of our volitional photo
taking on memory for visual and auditory aspects
of an experience.
It refers to photographic memory,
not in the context of photographic memory
that we normally hear about where people are truly photographic,
look at a page and somehow absorb all that information
and commit it to memory,
but rather the use of camera photographs
or the use of mental camera photographs,
literally looking at something and deciding blink
and snapping a, so to speak, snapping a snapshot
of whatever it is that you are looking at
remembering the content.
Two years ago, I was in an Uber and I looked out the window
and it was a street scene.
I was actually in New York at the time.
And I decided for reasons that are still unclear to me
to take a mental snapshot of this city street image,
even though nothing interesting in particular was happening.
And I do recall that there was a guy wearing a yellow shirt,
walking, there was some construction, et cetera.
I can still see that image in my mind's eye
because I took this mental snapshot.
This paper addresses whether or not this mental snapshotting thing
is real and a real.
and raise the hypothesis that if people are allowed
to choose what they take photos of,
that taking photos, again, this is with a camera,
not mental snapshotting, that taking those photos
would actually enhance their memory for those objects,
those places, those people,
and in fact, details of those object places and people.
And indeed, that's what they found.
What does this mean?
It means that if you really wanna remember something
or somebody, take a photo of that thing or person,
pay attention while you take the photo,
but it doesn't really mean.
matter if you look at the photo again.
That framing up of the photograph
stamps down a visual image in your mind
that is more robust at serving a memory
than had you just looked at that thing with your own eyes.
Very interesting and it raises all sorts of questions
for me about whether or not it's because you're framing up
a small aperture, a small portion of the visual scene.
That's one logical interpretation,
although they didn't test that.
The reason I find this so interesting is that
a lot of what we try and learn is visual.
And for a lot of people,
the ability to learn visual information,
feels challenging and we'll look at something
and we'll try and create some detailed understanding of it.
We'll try and understand the relationships
between things in that scene.
It does appear based on the study
that the mere decision to take a mental snapshot,
like, okay, I'm gonna blink my eyelids
and I'm gonna take a snapshot of whatever it is I see
can actually stamp down a visual memory
much in the same way that a camera can stamp down
a visual memory, of course,
through vastly distinct mechanisms.
No discussion of memory would be complete
without a discussion of the ever intriguing phenomenon
known as deja vu.
The way this works has been defined largely
by the wonderful work of Sissumu Tonagawa
at Massachusetts Institute of Technology, MIT.
I should also mention the beautiful work
of Mark Mayford at the Scripps Institute
and UC San Diego.
Here's what they discovered.
They evaluated the patterns of neural firing
in the hippocampus as subjects learn new things.
Neuron A fires, then neuron B fires,
then neuron C.
he fires in a particular sequence.
Again, the firing of neurons in a particular sequence,
like the playing of keys on a piano in a particular sequence,
leads to a particular song on the piano
and leads to a particular memory
of an experience within the brain.
They then used some molecular tools and tricks
to label and capture those neurons
such that they could go back later
and activate those neurons in either the same sequence
or in a different sequence
to the one that occurred,
during the formation of the memory.
And to make a long story short,
and to summarize multiple papers published
in incredibly high tier journals,
journals like nature and science,
which are extremely stringent, found
that whether or not those particular neurons
were played in the precise sequence
that happened when they encoded the memory,
or whether or not those neurons were played
in a different sequence,
or even if those neurons were played,
activated that is, all at once,
with no temporal sequence, all firing in concert,
all at once, evoked the same behavior
and in some sense the same memory.
So at a neural circuit level, this is deja vu.
Whether or not the same sort of phenomenon occurs
when you're walking down the street
and suddenly you feel as if, wow,
I feel like I've been here before.
You meet someone and you feel like, gosh,
I feel like I know you.
I feel like there's some familiarity here
that I can't quite put my finger off.
We don't know for sure that that's what's happening,
but this is the most mechanistic and logical explanation
for what has for many decades, if not hundreds of years,
has been described as deja vu.
I'd like to cover one additional tool
that you can use to improve learning and memory.
This is based on a paper from none other
than Wendy Suzuki at New York University.
The title of this paper will tell you a lot about where we're going.
The title is brief daily meditation enhances attention,
memory, mood, and emotional regulation
in non-experienced meditators.
This is a study that involves subjects aged 18 to 45,
none of whom were experienced meditators prior to this study.
There were two general groups in this study.
One group did a 13 minute long meditation,
and this meditation was a fairly conventional meditation.
They would sit or lie down.
They would do somewhat of a body scan,
evaluating for,
for instance, how tense or relaxed they felt
throughout their body and they would focus on their breathing,
trying to bring their attention back to their breathing
and to the state of their body as the meditation progressed.
The other group, which we can call the control group,
listen to, of all things, a podcast for an equivalent amount of time,
but they were not instructed to do any kind of body scan
or pay attention to their breathing.
Every subject in the study, either meditated daily
or listened to an equivalent duration podcast daily
for a period of eight weeks.
So the takeaway,
from the study are severalfold.
First of all, that daily meditation of 13 minutes
can enhance your ability to pay attention and to learn.
It can truly enhance memory.
However, you need to do that for at least eight weeks
in order to start to see the effects to occur.
And we have to presume that you have to continue
those meditation training sessions.
In fact, they found that if people only did four weeks
of meditation, these effects didn't show up.
Now, eight weeks might seem like a long time,
but I think that 13 minutes
the day is not actually that big of a time commitment.
And the results of this study certainly incentivize me
to start adopting a, I'm going for 15 minutes a day now.
I've been an on and off meditator for a number of years.
I've been pretty good about it lately,
but I confess I've been doing far shorter meditations
of anywhere from three to five or maybe 10 minutes.
I'm gonna ramp that up to 15 minutes a day.
And I'm doing that specifically to try and access
these improvements in cognitive ability
and our abilities to learn.
Today we covered a lot of aspects of memory
and how to improve your memory.
However, for sake of what was discussed today,
please understand that any number of different neurochemicals
can evoke or can increase the amount of adrenaline
that's circulating in your brain and body.
It really doesn't matter how you evoke the adrenaline release
because remember, adrenaline is the final common pathway
by which particular experiences, particular perceptions,
are stamped into memory,
which answers our very first question raised
at the beginning of the episode.
which is why do we remember anything at all?
Right?
That was the question that we raised.
Why is it that from morning till night
and throughout your entire life,
you have tons of sensory experience,
tons of perceptions, why is it that some are remembered
at others or not?
While I would never want to distill an important question
such as that down to a one molecule type of answer,
I think we can confidently say,
based on the vast amount of animal and human research data,
that epinephrine, adrenaline,
and some of the other chemicals that it acts with in concert
is in fact the way that we remember particular events
and not all events.
Once again, thank you for joining me today
to discuss the neurobiology of learning and memory
and how to improve your memory using science-based tools.
And last but certainly not least,
thank you for your interest in science.