Huberman Lab - Essentials: The Neuroscience of Speech, Language & Music | Dr. Erich Jarvis
Episode Date: April 23, 2026In this Huberman Lab Essentials episode, my guest is Dr. Erich Jarvis, PhD, a professor and Head of the Laboratory of Neurogenetics of Language at Rockefeller University and an investigator at the How...ard Hughes Medical Institute (HHMI). We discuss the brain circuits and genes underlying spoken language and why the ability to learn and produce vocalizations is extraordinarily rare in the animal kingdom. We also explore why song likely evolved before language, how gesture and movement share deep neural roots with speech, the neurobiology of stuttering, why childhood is the optimal window for language acquisition, and how physical movement — including dance — may help preserve speech and cognitive function across a lifetime. Read the show notes at hubermanlab.com. Thank you to our sponsors AG1: https://drinkag1.com/huberman Function: https://functionhealth.com/huberman Eight Sleep: https://eightsleep.com/huberman Timestamps (00:00:00) Speech & Language (00:00:23) Speech vs. Language; Brain Pathways for Communication (00:01:57) Gesture, Hand Movement & Speech Evolution (00:04:31) Sponsor: Function (00:05:59) Innate Vocalizations vs. Learned Speech (00:08:01) Evolution of Spoken Language; Neanderthals & Vocal Learning (00:09:29) Birdsong & Human Speech; Brain Circuit Parallels (00:13:22) Hummingbirds; Vocal Learning Species & Complex Traits (00:14:32) Critical Periods & Learning Your Native Song (00:16:50) Pidgin Language & Cultural-Genetic Convergence (00:18:36) Sponsor: AG1 (00:20:01) Genes Specialized in Speech Circuits (00:23:05) Critical Period for Language Learning; Multilingualism (00:25:17) Music, Emotion & Semantic vs. Affective Communication (00:28:14) Sponsor: Eight Sleep (00:29:49) Facial Expression & Speech Circuitry (00:31:07) Written Language & Neural Pathways (00:32:47) Stuttering; Basal Ganglia & Neurobiological Basis (00:35:03) Texting & Language Evolution (00:36:36) Tool: Movement, Dancing & Singing to Maintain Cognitive Health (00:38:43) Recap Disclaimer & Disclosures Learn more about your ad choices. Visit megaphone.fm/adchoices
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.
I'm Andrew Huberman, and I'm a professor of neurobiology and ophthalmology at Stanford School of Medicine.
And now, for my discussion with Dr. Eric Jarvis.
Eric, so great to have you here.
Thank you.
Very interested in learning from you about speech and language.
In terms of the study of speech and language and thinking about how the brain organizes speech and language, what are the similarities? What are the differences? How should we think about speech and language? There really isn't such a sharp distinction. Let me tell you how some people think of it now, that there's a separate language module in the brain that has all the algorithms and computations that influence the speech pathway on how to produce sound and the auditory pathway on how to perceive.
and interpret it for speech or for, you know, sound that we call speech.
I don't think there is any good evidence for a separate language module.
Instead, there is a speech production pathway that's controlling our larynx, controlling our jaw
muscles that has built within it all the complex algorithms for spoken language.
And there's the auditory pathway that has built within it all the complex algorithms for
understanding speech, not separate from a language module. And this speech production pathway
is specialized to humans and parrots and songbirds, whereas this auditory perception pathway
is more ubiquitous amongst the animal kingdom. And this is why dogs can understand sit,
see, come here, boy, get the ball and so forth. Dogs can understand several hundred human
speech words, great apes, you can teach them for several thousand, but they can't say a word.
What do we understand about modes of communication that are like language but might not be what
would classically be called language? Right. So next to the brain regions that are controlling
spoken language are the brain regions for gesturing with the hands. And that hand parallel pathway
has also complex algorithms that we can utilize. And some species are more advanced,
in these circuits, whether it's sound or gesturing with hands and some are less advanced.
Humans are the most advanced at spoken language, but not necessarily as big a difference at gestural language
compared to some other species. So as you and I are talking here today and people who are listening
but can't see us, we're actually gesturing without our hands as we talk without knowing it or
doing it unconsciously. And if we were talking on a telephone,
I would have one hand here and I'd be gesturing with the other hand
without even you seeing me, right?
And so why is that?
Some have argued, and I would agree, based upon what we've seen,
is that there is an evolutionary relationship
between the brain pathways that control speech production and gesturing.
And the brain regions I mentioned are directly adjacent to each other.
And why is that?
I think that the brain pathways that control speech evolved
out of the brain pathways that control body movement.
All right. And that's when you talk about Italian, French, English, and so forth,
each one of those languages come with a learned set of gestures that you can communicate with.
Now, how is that related to other animals? Well, Cocoa, a gorilla, who is raised with humans for 39 years or more,
learned how to do gesture, communication, learn how to sign language, so to speak, right?
but Coco couldn't produce those sounds.
Coco could understand them as well
by seeing somebody sign
or hearing somebody produce speech,
but Coco couldn't produce it with her voice.
And so what's going on there is that
a number of species, not all of them,
a number of species have motor pathways in the brain
where you can do learn gesturing,
rudimentary language if you want and say with your lens,
even if it's not as advanced as humans.
but they don't have this extra brain pathway for the sound.
So they can't gesture with their voice
in the way that they gesture with their hands.
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One thing that I've wondered about for a very long time is whether or not primitive emotions
and primitive sounds are the early substrate of language.
When I smell something delicious,
I typically inhale more and I might say,
or something like that.
Whereas if I smell something putrid,
I typically turn away, I wince, and I will exhale,
trying to not ingest those molecules
or inhale those molecules.
I could imagine that these are the basic
dark and light contrasts of the language system.
this kind of primitive to more sophisticated pyramid of sound to language.
Is this a crazy idea?
Do we have any evidence this is the way it works?
No, it's not a crazy idea.
And in fact, you hit upon one of the key distinctions in the field of research that I started out in,
which is vocal learning research.
Most vertebrate species vocalize, but most of them are producing innate sounds.
that they're born with, that is, babies crying, for example, or dogs barking.
And only a few species have learned vocal communication, the ability to imitate sounds.
And that is what makes spoken language special.
When people think of what's special about language, it's to learn vocalizations.
That is what's rare.
So all the things you talked about, the breathing, the grunting, and so forth, a lot of that
is handled by the brainstem circuits, you know, right around the level of your neck.
below, like a reflex kind of thing.
So or even some emotional aspects of your behavior in the hypothalamus and so forth.
But for a learned behavior, learning how to speak, learning how to play the piano, teaching
a dog to learn how to do tricks is using the four brain circuits.
And what has happened is that there's a lot of four brain circuits that are controlling,
learning how to move body parts in these species, but not for the vocalizations.
but in humans and in parrots and some other species,
somehow we acquired circuits where the forebrain has taken over the brain stem
and now using that brainstem not only to produce the innate behaviors
or vocal behaviors but the learned ones as well.
Do we have any sense of when modern or sophisticated language evolved?
Amongst the primates, which we humans belong to,
we are the only ones that have this advanced vocal learning ability.
Now, when you, it was assumed that it was only Homo sapiens.
Then you can go back in time now based upon genomic data, not only of us living humans,
but of the fossils that have been found for Homo sapiens, of Neanderthals, of Denisovan individuals,
and discover that our ancestor, our human ancestors, supposedly hybridized with these other hominid species.
and it was assumed that these other hominid species don't learn how to imitate sounds.
I don't know of any species today that's a vocal learner that can have children with a non-vocal
learning species. I don't see it. Doesn't mean it didn't exist. And when we look at the genetic
data from these ancestral hominids that, you know, where we can look at genes that are involved
in learn vocal communication, they have the same sequence.
as we humans do, for genes that function in speech circuits.
So I think Neanderthals had spoken language.
I'm not gonna say it's as advanced as what it is in humans,
I don't know.
But I think it's been there for at least between 500,000
to a million years.
Maybe we could talk a little bit more about the overlap
between brain circuits that control language and speech
and humans and other animals.
I was weaned in the neuroscience era
where birdsong and the ability of birdsong
to learn their tutor's song was and still is a prominent field,
subfield of neuroscience, and this notion of a critical period,
a time in which languages learned more easily
than it is later in life.
And the names of the different brain areas were quite different.
One opens the textbooks, we hear vernequies and brokhas for the humans,
and you look at the birds of it, I remember
you know,
HBC.
Robust Arch striatum, area X.
That's right.
How similar or different are the brain,
a brain area is controlling speech and language and say a songbird and a young human child.
Yeah. So going back to the 1950s or even a little earlier, and Peter Mahler and others who got
involved in neuroethology, the study of neurobiology of behavior in a natural way, right?
You know, they start to find that behaviorally there are these species of birds like songbirds
and parents, and now we also know hummingbirds, just three of them, out of the 40-something.
bird groups out there on the planet orders,
that they can imitate sounds like we do.
And so that was a similarity.
In other words, they had this kind of behavior
that's more similar to us than chimpanzees have with us
or than chickens have with them, right?
They're close to relatives.
And then they discovered even more similarities,
these critical periods,
that if you remove a child,
this unfortunately happens where a child is feral
and is not raised with human
and goes through their puberty phase of growth,
becomes hard for them to learn a language as an adult.
So there's this critical period where you learn best.
And even later on, when you're in regular society, it's hard to learn.
Well, the birds undergo these same thing.
And then it was discovered that if they become deaf,
we humans become deaf,
our speech starts to deteriorate without any kind of therapy.
if a non-human primate or, you know,
or let's say a chicken becomes deaf,
their vocalizations don't deteriorate, very little at least.
Well, this happens in the vocal learning birds.
So there were all these behavioral parallels that came along with a package.
And then people looked into the brain, Fernando Nadeva,
my former PhD advisor, and began to discover the area X you talked about,
the robust nucleus of the archipelium.
and these brain pathways were not found in the species who couldn't imitate.
So there was a parallel here.
And then jumping many years later, I started to dig down into these brain circuits
to discover that these brain circuits have parallel functions with the brain circuits for humans,
even though they're by a different name like Broca's and laryngeumotocortex.
And most recently, we discovered not only the actual circuitry and the connectivity are similar,
but the underlying genes that are expressed in these brain regions
in a specialized way, different from the rest of the brain,
are also similar between humans and songbirds and parrots.
So all the way down to the genes,
and now we're finding the specific mutations are also similar,
not always identical, but similar,
which indicates remarkable convergence
for a so-called complex behavior in species separated by 300 million years
from the common ancestor.
And not only that, we are discovering that
mutations in these genes that cause speech deficits in humans, like in FoxP2, if you put those
same mutations or similar type of deficits in these vocal learning birds, you get similar
deficits. So convergence of the behavior is associated with similar genetic disorders of the
behavior. Do hummingbirds sing or do they hum? Hummingbirds hum with their wings and sing with
their syrings. In a coordinated way? In a coordinated way. There is some speech.
species of hummingbirds that actually will,
Doug Ashwler showed this, that will flap their wings
and create a slapping sound with their wings
that's in unison with their song.
And you would not know it, but it sounds like a particular syllable
in their songs, even though it's their wings
and their voice at the same time.
Hummingbirds are clapping to their song.
Clapping, they're snapping their wings together,
in unison with a song to make it like, if I'm going,
bat-da-da-da-da-da-bat-da, you know,
and I banged on the table,
except they make it almost sound like their voice with their wings.
What's amazing about hummingbirds,
and I were going to say vocal learning species in general,
is that for whatever reason,
they seem to evolve multiple complex traits.
You know, this idea that the evolving language,
spoken language in particular,
comes along with a set of specializations.
When I was coming up in neuroscience, I learned that, I think it was the work of Peter Marler, that young birds learn, songbirds, learn their tutor's song and learn it quite well, but that they could learn the song of another tutor.
In other words, they could learn a different, and for the listeners, I'm doing air quotes here, a different language, a different bird song, different than their own species song.
but never as well as they could learn their own natural genetically linked song.
Genetically linked, meaning that it would be like me being raised in a different culture
and that I would learn the other language,
but not as well as I would have learned English.
This is the idea.
Yes.
Is that true?
That is true.
Yes.
And that's what I learned growing up as well and talk to Peter Mahler himself about before he passed.
Yeah, he used to call it the end.
innate predisposition to learn.
All right.
So, which would be kind of the equivalent in the linguistic community of universal grammar.
There is something genetically influencing our vocal communication on top of what we learn
culturally.
And so there is this balance between the genetic control of speech or a song in these
birds and the learned cultural control.
And so, so yes, if you were to take.
you know, I mean, in this case, we actually tried this at Rockefeller later on,
take a zebrafinch and raise it with a canary.
It would sing a song that was sort of like a hybrid in between.
We call it a caninch, right?
And vice versa for the canary.
Because there's something different about their vocal musculature
or the circuitry in the brain.
And with a zebra finch, even with a closely related species,
if you would take a zebra finch, a young animal,
and in one cage next to it,
place its own species, adult male, right?
And in the other cage, place a Bengalis finch next to it.
It would preferably learn the song from its own species neighbor.
But if you remove its neighbor,
it would learn that Bengalis finch very well.
Fantastic.
So it has something to do with also the social bonding with your own species.
That raises a question that based on something,
I also heard, but I don't have any scientific peer-reviewed publication to point to, which is this
idea of pigeon, not the bird, but this idea of when multiple cultures and languages converge in a
given geographic area, that the children of all the different native languages will come up with
their own language, I think this was in island culture, maybe in Hawaii, called Pigeon, which is
sort of a hybrid of the various languages that their parents speak at home and that they themselves speak,
and that somehow pigeon, again, not the bird, but a language called pigeon for reasons I don't know,
harbors certain basic elements of all language.
Is that true?
Is that not true?
What is going on here is cultural evolution remarkably tracks genetic evolution.
So if you bring people from two separate populations together that have been in their separate populations evolutionarily at least for hundreds,
of generations. So someone's speaking Chinese, someone speaking English. And that child then's learning
from both of them, yes, that child's going to be able to pick up and merge phonemes and words
together in a way that an adult wouldn't. Because why they're experiencing both languages
at the same time during their critical period years in a way that adults would not be able to
experience. And so you get a hybrid. And the lowest common denominator is going to be what they share.
And so the phonemes that they've retained in each of their languages is what's going to be,
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So we've got brain circuits in songbirds and in humans that in many ways are similar, perhaps not in their exact wiring, but in their basic contour of wiring, and genes that are expressed in both sets of neural circuits in very distinct species that are responsible for these phenomenon we're calling speech and language.
I mean, what are these genes doing?
One of the things that differ in the speech pathways of us
and these song pathways of birds
is some of the connections are fundamentally different
than the surrounding circuits,
like a direct cortical connection
from the areas that control vocalizations in the cortex
to the motor neurons that control the larynx in humans
or the serings and birds.
And so we actually made a prediction
that since some of these connections differ,
we're going to find genes that control neuroconnectivity
and that specialize in that function that differ.
And that's exactly what we found.
Genes that control,
what we call axon guidance and form incident connections.
And what was interesting,
it was sort of in the opposite direction that we expected.
That is, some of these genes,
actually a number of them that control neural connectivity
were turned off in the speech circuit.
All right.
And it didn't make sense to us at first,
and so we started to realize the function of these genes
are to repelled connections from forming.
So repulsive molecules.
And so when you turn them off,
they allow certain connections to form
that normally would have not formed.
So by turning it off,
you got to gain a function for speech, right?
Other genes that surprised us
were genes involved in calcium buffering,
neuroprotection,
like a parvalamine or a heat shock protein.
So when your brain gets hot,
these proteins turn on.
And we couldn't figure out for a long time,
why is that the case?
And then the idea popped to me one day and said,
ah, when I heard the larynx is the fastest firing muscles in the body.
All right?
In order to vibrate sound and modulate sound in the way we do,
you have to control, you have to move those muscles,
you know, three to four to five times faster than just regular walking or running.
And so when you stick electrodes in the brain areas that control learn vocalization,
in these birds and I think in humans as well,
those neurons are firing at a higher rate
to control these muscles.
And so what is that going to do?
You're going to have lots of toxicity in those neurons
unless you upregulate molecules
that take out the extra load
that is needed to control the larynx.
And then finally, a third set of genes
that are specialized in these speed circuit
are involved in neuroplasticity.
Neuroplasticity, meaning allowing the brain circuit
the brain circuits to be more flexible so you can learn better.
And why is that?
I think learning how to produce speech is a more complex learning ability than, say,
learning how to do tricks and jumps and so forth that dogs do.
In terms of plasticity of speech and the ability to learn multiple languages,
but even just one language, what's going on in the so-called critical period?
And then the second question is,
if one can already speak more than one language
as a consequence of childhood learning,
is it easier to acquire new languages later on?
Actually, the entire brain is undergoing a critical period development,
not just the speech pathways.
And so it's easier to learn how to play a piano.
It's easier to learn how to ride a bike for the first time and so forth
as a young child than it is later in life.
The brain can only hold so much information.
and if you are undergoing rapid learning to acquire new knowledge,
you also have to put memory or information in the trash, like in a computer.
You only have so many gigabytes of memory.
Plus, also for survival, you don't want to keep forgetting things.
And so the brain is designed, I believe, to undergo this critical period
and solidify the circuits with what you learned as a child
and you use that for the rest of your life.
And now the question you asked about
if you learn more languages as a child,
is it easier to learn as an adult?
And that's a common finding out there in the literature.
There's some that argue against it.
But for those that support it,
the idea there is
you are born with a set of innate sounds
you can produce a phonemes
and you narrow that down
because not all languages use all of them.
And so you narrow down the ones you use
to string the phonemes together
in the words that you learn.
and you maintain those phonemes as an adult.
And here it comes along another language
that's using those phonemes or in different combinations
you're not used to.
And therefore, it's like starting from first principles.
But if you already have them in multiple languages that you're using,
then it makes it easier to use them in another third or fourth language.
So it's not like your brain has maintained greater plasticity,
is your brain has maintained greater ability to produce different sense.
sounds that then allows you to learn another language faster.
What about modes of speech and language that seem to have a depth of
emotionality and meaning but for which it departs from structured language?
I think of musicians like there are some Bob Dylan songs that to me, I understand the individual words.
I like to think there's an emotion associated with it.
At least I experience some sort of emotion and I have a guess about what he was experiencing.
But if I were to just read it linearly without the music and without him singing it or somebody singing it like him, it wouldn't hold any meaning.
So in other words, words that seem to have meaning but not associated with language, but somehow tap into an emotionality.
Absolutely.
So we call this difference semantic communication, communication with meaning, and effective communication, communication that has more of an emotional feeling.
content to it. I believe, you know, based upon imaging work and work we see in birds,
when birds are communicating semantic information in their sounds, which is not too often,
but it happens, versus effective communication, sing because I'm trying to attract the mate,
my courtship song, or defend my territory. It's the same brain circuits. It's the same speech-like
or song circuits are being used in different ways. There's several other points here. I think
it's important for those listening out there to hear is that when I say also this effective
and semantic communication being used by similar brain circuits, it also matters the side of the
brain. In birds and in humans, there's left-right dominance for learned communication, learned-sound
communication. So the left in us humans is more dominant for speech. But the right has
more balance for singing or processing musical sounds as opposed to processing speech.
Both get used for both reasons. And so when people say your right brain is your artistic brain
and your left brain is your thinking brain, this is what they're referring to. And so that's another
distinction. The second thing that's useful to know is that all vocal learning species
use their learned sounds for this emotional, effective kind of communication.
but only a few of them, like humans and some parrots and dolphins,
use it for the semantic kind of communication we're calling speech.
And that has led a number of people to hypothesize
that the evolution of spoken language of speech evolved first for singing,
for this more like emotional kind of made attraction,
like the Jennifer Lopez, the Ricky Martin kind of songs and so forth.
and then later on, it became used for abstract communication like we're doing now.
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I'd love to chat a moment about facial expression, many of which are subconscious.
We are all familiar with the fact that when what somebody says doesn't match some specific
feature of their facial expression, that it can call, you know, that mismatch can cue our attention.
Yeah.
So how does motor circuitry that controls facial expression map onto the brain circuits that control
language, speech, and even bodily and hand movements?
Yeah.
You ask a great question because we both know some colleagues like Munwick-Frivol
at Rockefeller University who study facial expression and the neurobiology behind it.
Non-human primates have a lot of diversity in their facial expression like we humans do.
And what we know about the neurobiology of brain regions controlling those muscles of the face
is that these non-human primates and some other species that don't learn how to imitate vocalizations,
they have strong connections from the cortical regions
to the motor neurons that control facial expressions.
And even though it's more diverse in these non-human primates,
there was already a pre-existing diversity of communication,
whether it's intentional or unconscious,
through facial expression in our ancestors.
And on top of that, we humans now add the voice,
along with those facial expressions.
So it's like an email too.
You're emailing and someone says something by email.
Someone can interpret that angrily or gently.
And it becomes ambiguous.
The facial expressions get rid of that ambiguity.
I'm so glad you brought that out because my next question was and is about written language.
What is the process of going from a thought to language to written word?
And what's going on there?
What do we know about the neural circuitry?
What I think is going on is to a...
explain what you're asking is about
that I'm going to take it from the perspective
reading something. You read
something on a paper. The signal
from the paper goes through your eyes.
It goes to the back of your brain to your
visual cortical regions eventually.
That visual signal
then goes to your speech pathway
in the motor cortex in front here in
Broca's area and you
silently speak what you read
in your brain without moving your muscles.
Sometimes, actually
if you put electrodes, EMG,
electrodes on your larynge
muscles, even on burge you can do this,
you'll see activity there
while reading or
trying to speak silently, even
though no sounds coming out.
And so your
speech pathway is now
speaking what you're reading.
Now to finish
it off, that signal is sent
to your auditory pathway so you can hear
what you're speaking in your own head.
That's incredible. And this is why it's
complicated. Oh, and then you've got
right, right? Okay, here comes the fourth one. Now the hand areas next to your speech pathway
has got to take that auditory signal or even the adjacent motor signals for speaking and
translate it into a visual signal on paper. So you're using at least four brain circuits,
which includes the speech production and the speech perception pathways to write.
Stutter is a particularly interesting case. What is the current neurobiological understanding of
stutter and what's being developed in terms of treatments for stutter?
Yeah, so we actually accidentally came across stuttering in saumbirds,
and we've published several papers on this to try to figure out the neurobiological basis.
The first study we had was a brain area called the basal ganglia,
the striatum part of the basal ganglia involved in coordinating movements,
learning how to make movements,
when it was damaged in these, in this, in a speech.
like pathway in these birds, what we found is that they started to stutter as the brain region
recovered. And unlike humans, they actually recovered after three or four months. And why is that
the case? Because bird brains undergoes new neurogenesis in a way that human or mammal brains don't.
And it was the new neurons that were coming in into the circuit, but not quite, you know,
with the right proper activity
was resulting in this stuttering
in these birds.
And after it was repaired,
not exactly the old song came back
after the repair,
but still it recovered a lot better.
And it's now known,
they call this neurogenics
stuttering in humans,
would damage to the basal ganglia
or some type of disruption
to the basal ganglia at a young age
also causes stuttering in humans.
And even those who are,
born with stuttering, it's often the basal ganglia that's disrupted in some other brain circuit.
And we think the speech part of the basal ganglia.
Can adults who maintain a stutter from childhood repair that stutter?
There are ways to overcome the stuttering through behavioral therapy.
And I think all of the tools out there have something to do with sense.
motor integration. Controlling what you hear with what you output in a thoughtful, controlled way
helps reduce the stuttering. Texting is a very, very interesting evolution of language. I wonder sometimes
whether or not we are getting less proficient at speech because we are not required to write and
think in complete sentences. What do you think is happening to language? What do you think is happening to language?
Are we getting better at speaking, worse at speaking, and what do you think the role of things like texting and tweeting and shorthand communication, hashtagging?
What's that doing to the way that our brains work?
Texting actually has allowed for more rapid communication amongst people.
It's more like a use it or lose it kind of a thing with the brain.
The more you use a particular brain region or circuit, the more enhanced.
It's like a muscle.
The more you exercise it, the more healthier it is, the bigger it becomes, and the more space it takes,
and the more you lose something else.
So I think texting is not decreasing the speech prowess or the intellectual prowess of speech.
It's converting it and using it a lot in a different way.
In a way that may not be as rich in regular writing,
because you can only communicate so much nuance in.
short term writing. But whatever is being done, you got people texting hours and hours and hours
on the phone. So whatever your thumb circuit is going to get pretty big, actually.
For those listening who are interested in getting better at speaking and understanding languages,
are there any tools that you recommend? Should kids learn how to read hard books and simple books?
What do you recommend? Should adults learn how to do that? Everyone wants to know how to
keep their brain working better, so to speak, but also I think people want to be able to speak
well and people want to be able to understand well.
Yeah.
What I've discovered personally, right, is that so when I switch from pursuing a career
in science from a career in dance, I thought one day I would stop dancing.
But I haven't because I find it fulfilling for me.
And there have been periods of time like during the pandemic where I slowed down on dancing
and so forth.
And when you do that, you realize, okay, there are parts of your body where your muscle tone decreases a little bit and somewhat.
Or you could start to gain weight.
I somehow don't gain weight that easily.
And I think it's related to my dance.
If that's meaningful to your audience.
But what I found is in science, we like to think of a separation between movement and action and cognition.
And there is a separation between perception and production.
Cognition being perception, production being movement, right?
But if the speech pathways is next to the movement pathways,
what I discover is by dancing, it is helping me think.
It is helping keeping my brain fresh.
It's not just moving my muscles.
I'm moving or using the circuitry in my brain to control a whole big body.
You need a lot of brain tissue to do that.
And so I argue if you want to stay cognitively intact into your old age,
you better be moving and you better be doing it consistently whether it's dancing walking running
and also practicing speech oratory speech and so forth or singing is controlling the brain
circuits that are moving your facial musculature and it's going to keep your cognitive circuits
also in tune and i'm convinced of that from my own personal experience this has been an incredible
conversation and opportunity for me to learn and i know i speak for a tremendous number of people when i just
really want to say thank you for joining us today. You are incredibly busy. It's clear from your
description of your science and your knowledge base that you are involved in a huge number of things.
Very busy. So thank you for taking the time to speak to all of us. Thank you for the work that
you're doing. Thank you for inviting me here to get the word out to the community of what's going on
in the science world. We're honored and very grateful to you, Eric. Thank you.