Huberman Lab - Dr. David Linden: Life, Death & the Neuroscience of Your Unique Experience
Episode Date: August 21, 2023In this episode, my guest is Dr. David Linden, Ph.D., professor of neuroscience at Johns Hopkins University School of Medicine and the author of many popular books about the brain. We discuss individu...al differences between people — focusing on differences in how people sense the world around them and the roles that chance, heredity, and life experiences (even in utero) play in determining our physical and cognitive traits. We discuss the bidirectional connection between the mind and body and how our thoughts and mental practices (e.g., meditation and breathwork) impact our health. We also discuss the link between inflammation and depression. We also discuss Dr. Linden’s terminal illness diagnosis, his mindset during chemotherapy and what his diagnosis has taught him about the mind, gratitude, time perception and life. This episode also covers sensual touch, cerebellar function, and epigenetic inheritance and ought to be of interest to all interested in neuroscience, genetics, psychology and human development. For the full show notes, including articles, books, and other resources, visit hubermanlab.com. Take our survey and get 2 months of Huberman Lab Premium Thank you to our sponsors AG1: https://drinkag1.com/huberman ROKA: https://roka.com/huberman Levels: https://levels.link/huberman InsideTracker: https://insidetracker.com/huberman Supplements from Momentous https://www.livemomentous.com/huberman Timestamps (00:00:00) David Linden (00:03:59) Sponsors: ROKA & Levels; Huberman Lab Survey (00:07:54) Sensory Touch & Genitals, Krause Corpuscles (00:16:46) Sexual Experiences & Sensation (00:19:14) Human Individuality & Variation; Senses & Odor Detection (00:30:25) Sponsor: AG1 (00:31:22) Visual Individuality; Heat Tolerance; Early Life Experiences & Variation (00:40:28) Auditory Variability, Perfect Pitch (00:42:08) Heritability & Human Individuality: Cognitive & Physical Traits (00:49:36) Heritability, Environment, Personality; Twin Studies (01:00:12) Sponsor: InsideTracker (01:01:19) Development, Chance; Transgenerational Epigenetic Inheritance (01:07:37) Single Generation Epigenetic Inheritance & Stress; Autism (01:15:52) Sleep Paralysis; Cerebellum, Prediction (01:23:47) Nature vs. Nature, Experience; Linden Hypothesis (01:30:37) Mind-Body Interaction; Chemical Signals (01:39:10) Inflammation & Depression (01:43:35) Neuroplasticity, Inflammation & Mental Disorders; Microglial Cells, Exercise (01:52:15) Fads & Science (01:55:16) Mind-Body Communication; Cancer (02:03:28) Mind-Body, Mediation, Breathwork (02:07:30) Atrial Fibrillation, Synovial Sarcoma, Heart (02:14:22) Gratitude & Anger; Chemotherapy, Curiosity & Time Perception (02:19:58) Death, Brain & Future Prediction, Religion & Afterlife (02:24:15) Life Advice; Time Perception & Gratitude (02:34:35) Zero-Cost Support, YouTube Feedback, Spotify & Apple Reviews, Sponsors, Momentous, Social Media, Neural Network Newsletter Title Card Photo Credit: Mike Blabac Disclaimer
Transcript
Discussion (0)
Welcome to the Uberman Lab podcast where we discuss science and science-based tools for everyday life.
I'm Andrew Uberman and I'm a professor of neurobiology and
Ophthalmology at Stanford School of Medicine. Today my guest is Dr. David Linden.
Dr. David Linden is a professor of neuroscience at Johns Hopkins School of Medicine. His laboratory has studied
Neural Plasticity, that, how connections in the brain change
in response to experience.
Much of that work focused on a structure called
the cerebellum, which is also sometimes referred to
as the mini brain, because it looks like a mini brain
in the bottom and back of the human brain,
and it's responsible for an enormous number
of basic functions that we use in everyday life,
including our motor behavior, that is, our ability to walk and talk, but also dance, play instruments, and it's responsible for
an enormous number of basic functions that we use in everyday life, including our sense
of balance, our ability to learn new motor behaviors, as well as our sense of timing.
Today, we will discuss the cerebellum in what it does, but Dr. David Lindon will also
teach us about the important sense of touch, as well as what makes us different as individuals.
The reason today's discussion encompasses so many important topics is that Dr. David
Lindon's laboratory has focused on many of those topics, and he is also the author of
five excellent popular books about neuroscience.
The focus on, for instance, our sense of pleasure and where it
originates from and what controls it in the brain, as well as our sense of touch. And today we start
off our discussion by talking about the recent discovery of a set of neurons that have been known
about for a long period of time, but that only recently have been characterized that are involved
in sensual touch in particular, and it's a fascinating conversation, I assure you.
In addition to that, Dr. David Linden informs us
about what makes us individuals.
How each and every one of us perceives
the same things differently,
and it's an absolutely fascinating conversation,
which tells you, for instance,
why some of you think a smell is putrid,
indeed, smells like vomit,
whereas others, perhaps, are not bothered by that
smell and why others still are attracted to that smell, or something that you look at,
or something that you hear.
We also talk about nature versus nurture and how we come to be who we are, not just through
our genes and epigenetics, but also through our early childhood experience and adult experience.
And then in the latter third of our conversation, we shift to talking about the so-called mind-body
connection and the science underlying how our thoughts inform our bodily health or lack thereof,
as well as how the organs of our body control the chemicals, hormones, and thoughts within our brain.
Then we shift to discussing Dr. David Linden himself and the fact that in 2020,
he was diagnosed with a form of heart cancer that led his physicians to tell him that he
had six to 12 months to live. Now, obviously, because he was in our studio to record this
conversation, he has outlived that prognosis, but he lives day to day with the knowledge
that his death may very well come soon, although
it isn't clear exactly when that day will come, of course.
He tells us how the initial prognosis of his cancer, as well as outliving that prognosis,
has informed his day to day life, as well as his thinking and his relationships.
And that leads to a very direct and frankly emotional conversation that includes advice on how all of us can get the most out of our daily living and out of our overall life.
It's an extremely powerful conversation that I believe everyone, regardless of age or health status, can benefit from.
And it's one that makes clear that not only is Dr. David Linden a spectacular scientist, but also a spectacular educator, a spectacular
popular writer, a spectacular family man, including husband and father and friend to many people
and his colleagues. But he is also a courageous and spectacularly generous human being.
Before we begin, I'd like to emphasize that this podcast is separate from my teaching and
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for your interest in science. And now for my discussion with Dr. David Linden,
Professor Linden, welcome. Thanks so much for having me. I've been looking
forward to our conversation and we have a lot to talk about. We do. Lots of
different aspects of science, lots of different aspects of personal
journey and what you're confronting now as it relates to your health and your future.
I want to start off with a question that I learned from the one and only the great Carl
Diceroth, who was the first guest on this podcast. My colleague at Stanford, and for those of you
that don't recognize Carl's name,
he is an absolute phenom.
He's an active clinical psychiatrist.
So he's an MD, and he also is a bioengineer
who's developed a lot of the modern tools
for probing the brain.
And anytime I've met with Carl,
the first thing he says is,
what are you most excited about lately?
That's a good question. It is.
So I'm going to steal that approach and say,
what are you most excited about lately?
Well, very, very lately, the most interesting thing that I read in neuroscience is the answer to
a scientific problem that I think is really
dear to a lot of people's hearts and that is what are the nerve endings in
the genitals that are responsible for sexual sensation? And you know if you think
about it right people can feel sexy from being touched on lots of different parts of the
body, but there's something special about the genitals. Doesn't matter male or female
or intersex or gay or straight or bi or whatever you are, you know, the genitals are a hot
spot. And why? And you'd think as biologists, we'd know this by now. This would be something we could just answer.
But it's been a mystery for a long time.
And if you go back to 1860, there was a German
Neuronatomist named Krause.
And he cut thin sections of tissue from the penis
and the clitoris.
And he looked at them under the microscope.
And he saw a particular kind of nerve ending there
that has since been called the Kraus corpuscle,
and there were lots of them in these two places.
And so he thought, well, maybe this is the cellular basis
of sexual sensation, maybe these are the particular
nerve endings that are responsible for this.
But there were some things that were in favor of that findings that are responsible for this.
But there were some things that were in favor of that
and some not.
So these nerve endings are also in some other places
that people can find more or less sexy,
like they're in the nipples and they're in the lips
and they're in the anus, all places that get popular
in that domain. But they're in the anus, all places that get popular in that domain.
But they're also in places like the cornea or the lining of the joints.
So distribution doesn't quite make sense.
And so it was never known.
And so if you wanted to really test as a scientist whether these nerve endings are responsible,
you want to record their electrical signals
while the genitals are being touched.
You'd want to inactivate these cells
and see if you could interfere with sexual sensation.
And this, in a preprint from David Guinty's group at Harvard,
is just what they have been able to do in mice.
They found a way to label and record from and activate
and inactivate artificially the crows, corpuscles.
And so you see a nerve ending in the skin.
It could be conveying all kinds of information.
It could be tuned for hot or for cold or for itch or for pain
or for inflammation or for pain, or for inflammation, or for mechanical sensations, stretching vibration indentation,
and sure enough, when they recorded from these cross-corpolysis, they really are mechanical
sensors, as you would expect, if they were involved in sexual sensations.
So that was good.
And then the other thing, then they did is they tried
to artificially turn them on.
And so the way they did that is they used genetic tricks
to express one of Carl Diceroth's molecules
that activates neurons when blue light is shown on them.
And they found that if they express this artificial protein in the
cow cells in a male mouse and then shine blue light, the mouse gets an erection.
All right, so far so good. What happens if you turn them off? Well, if you turn them off
in a male mouse, it's just as interested in females when they're in heat, but it won't mount
and thrust and ejaculate as much. And if you turn them off in a female mouse
during the time of her cycle where she would normally be sexually receptive, you
find that she is much less interested. She's much less likely to let him
mount. She's much less likely to let him finish. So this is the remarkable
results that finally, after all these years, since 1860, now we know what the nerve endings are
that convey sexual sensation. And like all good science, then you know, there are a lot of questions that are really interesting to our everyday lives.
Like, you know, people like different things in bed and have different propensity for orgasm or like to be touched in different ways.
Well, is part of that reason because of individual variation in their crossows corpuscle structure.
We know that sexual sensation diminishes with aging.
Is that in part because crows corpuscle density
is lost from the skin of the genitals?
And that's a reasonable idea because we know for example,
that fine touch sensors in the fingertips,
so-called Merkel and Meisner endings, also named after German anatomists,
like so many things are, are also lost with age.
So that's a reasonable idea.
So this finding from Ginti's lab
has opened up a whole world of science.
And I've been, my own lab doesn't work on touch,
but I've been a fanboy of touch for many, many years,
mostly because where I work at Johns Hopkins Medical School, there have been many terrific
touch researchers.
It's been a world center for it.
And I hear about it over lunch and I got all fired up.
So years ago, I wrote a book about it and I still follow the field.
And this is the most interesting thing at Matt Field recently.
And as I recall, Gintie was your neighbor at Hopkins before he moved to Harvard.
That's right. That's right. He was one of the ones. Ginti, Steven,
Shao, Michael Katerina, Xinjiang, Dong. There have been a number of world leaders
in a cellular basis of touch sensation at Hopkins. Do you recall if in the preprint that you were describing,
there was an experiment where they activated these
Krause corpuscles in females?
It's funny.
You should mention that.
I sent that exact email to David Guinty,
and they said they are in the process of doing that right now,
and they don't quite know yet. And so I asked him. I said, so for example, is erection of the clitoris even a thing in
mice?
And he says, well, we're really not sure.
So we're activating the crows core puzzles in female mice.
And we're just kind of staring at it and looking and see if anything happens.
Just there, you know, does the, you know, does the, the body change? Shape is there a color change.
They don't even quite know what it is they're looking for because it's that much
on the leading edge of things, but it's a good question.
Yeah. Or perhaps the female mice would be more willing to mate outside of the
usual timeframe of receptivity if these cross-core puzzles are stimulated.
That's possible. My suggestion, my guess would be not,
because I think that the hormonal regulation of receptivity
is like a sledgehammer and very hard to overcome,
but they might be more willing to continue mating
or make for longer during their fertile time.
And I just wanna remind people
because we had a guest recently, Dr. Reena Malik,
who's a urologist, reproductive and sexual health expert,
she's an MD, and she made clear that the clitoris
and the penis come from the same embryonic origin.
They are analogous tissues in different individuals. I do have one more
question about this sexual touch thing. These are peripheral nerves, right? So these are not
of the brain and spinal cord, they're in what we call the periphery. And my understanding is that
peripheral neurons regenerate and can remodel themselves extensively in ways that
neurons within the brain and spinal cord tend to remodel less, especially as one gets older out of
the so-called critical period. Is it possible that these cross-corpuscles and their patterns of
innervation within the genitals change according to the stimulation that people experience.
In other words, is sexual sensation experienced dependent?
That is a great question.
And so we don't know because monitoring this in people is not technically possible, right? It requires cadaver to show. So you can only do it once.
In animals, it will be possible, and it could be for a couple of different reasons. In other words, it could be, I think what you're imagining is that there's actual structural plasticity. If you looked at these Krauss corpuscles, or that you would
actually see them changing their shape
or their size or their density as a
result of experience. But what can also
happen is a phenomenal like desensitization
that is to say when they're stimulation
for a long time, then the receptors transiently can become less sensitive
to touch.
And it's well-known, particularly in males, that chronic masturbation can produce desensitization
of sexual sensation in the penis.
And that could be as a result of a physical change,
a morphological change in the crowd's corpuscles,
but it's more likely to be a change in their function
that you wouldn't be able to simply see
by looking at an outline of their structure in the microscope.
Such an interesting topic.
Thanks for opening things up with that.
And I'll have to check out this preprint.
I'm also a huge fan of David Guinty's work and colleagues. There are many people involved in that domain of work, of course.
I'd like to talk about your recent book and the sort of underlying basis of what led you to write it. And what intrigued you about this idea of human individuality?
The book, Unique, is one that we'll provide a link to in the show note captions.
And it's a very interesting idea that we are all different, especially coming from a
neuroscientist who were trained at least similarly, to learn that sure the bumps and ripples of
the brain and the fine wiring of the brain is different and we are all unique and different.
We have different shapes, aka morphologies, but focusing on human individuality is not
something that modern neuroscience or classic neuroscience has really done much of.
It's really focused on how people do X or people do Y this way. Tell us about
unique and tell us about human individuality.
Yeah. Well, I mean, you're absolutely right. So when I look at the experiments in my
own lab, how do we do them? Well, we work on mice. Do we work on mice with genetic variation?
No. We work on highly inbred mice that are designed
to be as genetically similar to each other as possible.
And then we raise them basically in prison
in little cells, which may not be a good idea.
And we try to give them a similar experience as possible.
They are given toys and food and water,
but I agree.
It resembles a prison of sorts.
They aren't free to roam.
They have nothing like the experience of a wild mouse.
Let me put it that way.
They're, and yes, there are, as you said correctly,
there are plenty of experiments where there is enrichment
for mice, and they love it.
So for example, in our lab, when we put running wheels
in the cages or mice, mice and let them run overnight,
they're active at night.
Your average mouse will run two kilometers in a night for a little tiny mouse.
And some of the mice are so intense, they'll run 20 kilometers.
Imagine a mouse doing 20k, but it will happen.
They really, really like it.
They don't like being in prison. They want
to exercise, and they're really bored. So, yes, to get back to your general point, so much of science
is designed to try to find general principles of function of the brain, of physiology, of genetics,
and to ignore individual variation,
but individual variation is so important to our human experience,
and actually is so important to the process of evolution
and natural selection, and how species make their way in the world,
that it's something that requires a lot of attention.
And to me, what's really fascinating is that we can agree on a common reality at all, even within the human species.
And this is true of some senses more than others. Obviously in your world, in the retina, we have various kinds of loss of color vision that are well known and some other more complicated
phenomena having to do with impairments in the perception of motion or form. But the place where
this really happens is in the olfactory system. So we have approximately 400 functional
So we have approximately 400 functional receptors for different odorant molecule smells in our nose.
And if you sequence the genomes of many people, you find that the DNA that encodes for these odorant receptors is unusually variable from individual to individual. As a matter
of fact, if you take two different people on average, they will have functional differences
in 30% of their odor receptors. And if you do as Leslie Vossal and her colleagues did at Rockefeller University and give
odor tests where they give people different things to smell and then they dilute them and
find the threshold at which they can detect them, you find enormous changes from people to
people, both in general terms, some people are just better smellers than others, but in terms
of individual odors as well, there's some odors that some people can't detect and other
people smell one way, for example, there is a, there's a secretive hormone called Andrastinone.
Andrastinone, there are some people who can't smell at all. For some people, it smells like rather
pleasant, like cut grass. And for some people, it smells foul like your own or sweat. And
it just depends on genetic variation in one particular odorant receptor.
Sorry, I interrupt another phenomenal researcher who studies
olfaction among other things, Catherine Duluck. I once heard say that some
people have a gene that for them makes the smell of microwave popcorn. They
experience that smell as vomit and other people who lack this gene like the smell of microwave popcorn or at
least for them, it's not aversive.
So it can really be a binary response.
Well, it can.
And actually, that's a very particular funny case.
So the relevant chemical there is butaric acid and also isovaleric acid. And so there are researchers, I think Rachel Hertz
is one of them, who have given a mixture
of these two chemicals to people.
And if they say, this is Parmesan cheese, they go,
oh yeah, that's Parmesan cheese.
And if they give it to other people and say,
this is vomit, they'll go, oh yeah, that's vomit.
And if they tell people, they give them one vile and say, this is the premise of an
cheese and they go, yeah, and they give them another one and they say, it's vomit.
They go, yeah.
And then they say, well, actually we fooled you.
It was the same vile.
They said, no, you didn't.
You must have made a mistake.
They're convinced that they couldn't have been the same thing.
So this points out, not only is there genetic variation that is responsible for our individuals perceived odor, but we
are incredibly suggestible in terms of odors. And we are very dependent upon them in terms
of cultural context, and this can be learned. And this is central to our humanity,
in the sense that we humans are what I like to call
the anti-pandas.
Pandas live in one spot in Southern China,
and they eat one thing, bamboo.
And that's it.
Humans are the opposite.
Humans can live in any ecological niche in the
world from the tropics to the poles, and humans eat a wide, wide, wide variety of foods, and as a
result, it means that we have to have a very plastical factory system. There have to be very few things that we find innately
aversive. There are only a handful of odors rotting meat odors,
molecules with the evocative names like cadaverine and putracing are things that even babies
when they're newborn find aversive. But other things happen that they need to be learned. For example, pretty much every adult finds poop odors unpleasant, but babies happily play
with their own poop.
They have to learn that that's disgusting.
It's not because babies have a different nose.
It's because they have to learn culturally.
It's not innate.
It is not innate. It is not innate. There are only a few innate odor versions and a few innate taste
versions that we're born with and the other things are elaborated culturally. And we can think
about this in terms of how we talk about odors. So for example, we might say vanilla smells sweet.
Well, that's weird. Those are two different senses. How can something smell sweet? That's like saying it sounds red, right? It's a statement about synesthesia.
Right. But how did it come to pass? And do people say that vanilla smells sweet everywhere in the world? Well, the answer is no. So in places in the
world where vanilla is used with sugar in in sweet foods like desserts, then
people say that vanilla smell sweet or mint. Similarly, smell sweet, if it is
typically used together with sugar. But if you go to a place like Vietnam where mint is mostly used in savory dishes, people won't say that mint smells sweet.
So there's a paired association at
some point in development.
Yeah, it is.
It absolutely is a paired association, and it's something that goes on continually through
your life, right?
I mean, lots of people, for example, have stories of foods that they wouldn't eat as a child,
but they came to like as an adult.
A good example of that is coffee. A lot of people have
to overcome bitter aversion to become coffee-efficient autos. So, you know, this feeds into the more that there is no pure perception.
Perception is inference.
It's not like there is a purely objective world that can somehow make its way through
the senses, and we can perceive that as the truth.
All of our perception through all of our senses, both the outward pointing senses of the world,
like smell and taste and sight and hearing, and the inward pointing senses, like balance
and is my stomach full and things like that.
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D3K2. Again, that's drinkag1.com-huberman. Are there any examples of uniqueness of visual perception that come to mind?
I recently did a social media post that involved.
It was essentially three rings, a blue ring, a red ring, and a blue ring in the center.
Or perhaps it was the other way around.
Excuse me, it was red, blue, red, and I asked,
which ring is in front or are they all in the same plane?
Now, of course, it's a two-dimensional image.
And interestingly, it splits out into about thirds.
Some people see the blurring in front, quite a bit.
Others see a red ring out in front.
Others see them all in the same plane.
And this, we think think has to do with differences
in two things between individuals.
One is the distribution of the cone photoreceptors,
which we know is essentially random between individuals,
maybe even between the two eyes.
And that gives rise to this phenomenon of chromatic aberration, which is
the displacement of the visual image according to the wavelength of the light, and we won't
get into the physics of it now. I'll soon do a post that hopefully distills it in a manner
that's simple enough that people understand. But clearly, some people see certain colors
in front of others. And the person right next to them could see the opposite color in front and others say,
what are you talking about? All the colors are in exactly the same plane of vision. So that's the
one that I know. I'm guessing you know some others and perhaps some more robust ones. Well, I think,
you know, perhaps this is maybe not what you had in mind, but one way in which experience modifies the
visual world has to do with how much light you're exposed to in the first five years or
so of your life.
And so kids that don't get outside are much more likely to be myopic.
And it actually is...
Nearsighted.
Nearsighted, yes.
When they grow up, then kids who got outside
and we now know that at least part of the story
is that light seems to stimulate the expression
of a class of molecules called trophic factors that you're well acquainted with,
that actually changed the shape of the eyeball.
So it's not really the structure of the retina
or the lens of the cornea, the actual degree
of elongation of the eyeball changes,
changing the way the retina sits relative to the lens.
And that seems to be light dependent early in life,
and which gives rise to a higher incidence of myopia.
And to me, this is really, well, first of all,
it's news you can use, you should get your kids outside
for a lot of kinds of reasons.
And you should get outside too,
especially in the mornings,
yet that's circadian rhythm.
I know that's a famous,
supermanesque point.
They're gonna be putting me in the grave,
David, and I'm gonna be telling people to,
or maybe I'll be on my tombstone,
say get sunlight in your eyes,
especially on cloudy days,
because there is still sunlight,
even if you can't see the physical object of the sun, on cloudy days, because there is still sunlight, even if you can't see the physical object of the sun
on cloudy days.
Well, I think this whole idea of having traits
that are dependent upon early life experience
is fascinating because there are a number of situations
where you would guess that something is genetic, but it isn't.
It's actually dependent on early life experience. And there's an amazing story about this having to do
with the early days of World War II. So in the early days of World War II, the Japanese army just
swept through Asia. They defeated the British and Malaysia, and Singapore, they over in Thailand,
and Burma, and they were knocking on the gates of India, and everything was going great, except
the Japanese army had a problem. There were an enormous number of their soldiers who became
incapacitated with heatstroke. They got, their core temperature got too hot. And when the army doctors examined
them, they found this was much more likely to happen in soldiers who came from the northern
part of Japan, Hokkaido, where it snows in the winter, as opposed to the southern part
of Japan, like Kyushu, which is a semi-tropical
environment.
And the classical explanation, the biology like us would guess would say, oh, all right,
well, this has happened genetically over many years.
You have a family that's been in Q-shoe for many generations, and you've selected for
gene variants to allow you to tolerate the heat better.
And we know actually what this is.
So if you're more heat tolerant, it's because you have more of a particular class of sweat
gland called the Echroin sweat glands, the sort of salt water sweat glands, not the lipid-stinky
armpit sweat glands called the apricot ones, the Echroin ones.
You have a higher fraction of them that are innervated, meaning that the signals from your brain that say your
core is too hot can then make you sweat. So the total density of
sweat glands between northern and southern soldiers in Japan
wasn't different, but the southern soldiers tend to have a higher
degree of innervation. All right, so they said, okay, well this
happened genetically over many generations. But if you look at those rare cases where you have soldiers from a long
established northern family and their parents moved south and then they grew up in the southern
location, they had high sweat gland innovation. They were wealthy, tolerant. Conversely, if you had
a well-established southern Kyushu family and they moved to Hokkaido
and then had their child, that child developed the northern sweat gland, Intervation Pattern.
So, meaning less nerve-innovation of those sweat glands, as you mentioned before, just as
many sweat glands, just less nerve-innovation.
Therefore, those sweat glands could not be activated.
They couldn't dump heat as well.
Their heat tolerance was lower. Exactly right.
And what's wonderful is that this gives an advantage
that you can't get through evolution
and that it can happen right away
in one generation, right?
Evolutionary change is slow, right?
And you can adapt as a species and as a family
over many, many, many generations. But when you have a phenomenon that is set by early life
experience, well, then you can benefit from that early life experience within your own life. It's
not that you're great, great, great, great, great grandchildren will ultimately benefit you benefit. Another wonderful example of this comes
from field mice, voles, and we were talking earlier about how we both worked with the
scientist, Irv Zooker at Berkeley, who was a specialist in voles, and what people found is that if you take a wild caught
field mice and you have pregnant mothers and you have them in the lab, but you
manipulate the lights so that you have artificial spring. In other words, day length is getting longer day after day
during the pregnancy.
Then what happens is when their pups are born,
they will have a low density of fur,
anticipating summer temperatures.
If you, however, put them in artificial fall,
where day length is getting shorter, they will be born.
Now with high density of for anticipating winter temperatures, and of course, you can do this no matter
what the season actually is in the world by manipulating these lights in the lab.
And so, like the sweating Japanese soldiers, this is a great example of early life
plasticity, and just the sort of trait that if you asked them when they would probably
guess is heritable, but actually is not.
Thanks for mentioning Irv Zucker, who, as you also mentioned, was an advisor to us both,
who's done incredible work in circadian biology, seasonal rhythms, hormones and behavior.
I have such reverence for Irv and the experiment you mentioned made me smile wide because
it's but one of gosh, maybe hundreds of incredible studies.
So if people are interested in seasonal rhythms and circadian rhythms and biology of the most
interesting kind, definitely check out Irving Zucker's work at Berkeley.
I'll provide a link to his PubMed there. Since we've been taking a tour of individual variation
in OFAC3 perception, visual perception, and now heat tolerance, I have to ask, are you aware
of any examples off the top of your head in the auditory domain that particularly intrigue you.
Yeah, well, I would say one really interesting example,
how to do with perfect pitch.
So perfect pitch as a trait, that is to say, you have the ability
to to hear a note played and say, oh, that's a C sharp, right?
This is a pretty rare trait.
So even if you look among highly trained musicians,
if you went to Peabody Conservatory at my university,
Johns Hopkins, and tested people there,
you would find a higher incidence of perfect pitch
than you would in the general population,
but still maybe one in 10 trained musicians have perfect pitch.
And parenthetically, having perfect pitch doesn't necessarily make you a better musician,
but it's an interesting phenomena.
And so the question is, well, is perfect pitch heritable?
And the answer is when you look at twin studies,
which is what we use to estimate heritability, the answer is it's kind of low. There's a
heritable component, but it accounts for my recollection is on the order of 30-40% of the variability
in perfect pitch. However, if people receive ear training starting at a young age,
the chance that they will develop perfect pitch can improve drastically.
In your book, Unique, do you cover aspects of human
individuality that extend beyond the percept
chendomine into the cognitive domain?
Well, yeah, absolutely.
And, you know, I think it's good to set the stage here
if we're going to be talking about heritability
and human individuality.
And so if I can go off on a little bit of a riff
for the benefit of your listeners and viewers here.
So if you look at human traits,
whether they are behavioral traits like shyness or very
straightforward morphological traits like height, what you tend to find is that there
are very few traits that are entirely heritable, where all their variability can be predicted
based on the gene variance you get from your mother and father. And there are a few traits that are absolutely unheritable, but that most fall in between.
So let me give an example. Everyone in the world has either wet or dry your wax.
And it turns out that this is determined by variation in the single gene. The name of the gene is boring.
It's ABCC 11.
It's an ion transporter.
And there is a variation in this gene
gives rise to either wet or dry ear wax.
It doesn't matter how your parents raise you.
It doesn't matter what foods you ate growing up.
It doesn't matter what diseases your mother had when you were
on the womb, it's 100% heritable. Well, does this mean that ABCC 11, we should call it the
earwax type gene? Well, no, because it's not there just for that. Like this, this gene is expressed
in cells in all parts of the body, doing all kinds of things.
Ear wax is just something that we notice.
Genes don't code for traits, they code for proteins.
And so we have to be careful about how we refer to them in that way.
For example, the wet ear wax variant of the ABCC 11 gene also confers a slightly higher risk for breast cancer.
So clearly it's not just for earwax, it's for a bunch of things, most of which we
don't yet know about. But in the case of earwax, this trait is 100%
heritable. At the other end of the scale, speech accent is 0% heritable. It is entirely dependent upon the speech
that you experience in your childhood.
And interestingly, it's the speech of your peers
more than the speech of your family,
which is why the children of immigrants
sound like the place where they wound up,
not like their parents.
And there is no evidence for any degree of heredability,
not just to be clear, I'm talking about speech accent.
Like whether you have a high or a low voice
or it's nasal or more or less resonant,
these are physical things having to do with the vocal tract
and they are in part heritable.
Okay, so we've got one thing that's 100% heritable
and one thing that's 0% heritable,
but where do most things fall?
Most things fall in the middle.
One of the most heritable traits
that we know about in humans is height.
And in the United States, height is about 85% heritable.
85% of the variation in the trait of height
can be explained by what you inherit from your mother and your father.
Well, what's the rest? Well, it's nutrition, it's the diseases you fought off, it's also random variation, which we'll talk about a lot later.
Now, you might say, okay, well, that's an estimate for people in the US.
Is this true all over the world?
Well, no.
If you go to a place where people routinely don't get enough nutrition and are routinely
fighting off infectious diseases like this has been studied in rural Bolivia, for example,
a rural India, now height is no longer 85%
heritable. It's only 50% heritable. Why? Because people in these situations where they don't
get enough nourishment, where they're fighting off these diseases, can't live up to their genetic
potential for height. If you want to make things better for the people of the world, then everyone needs to have
basic things like the ability to learn and enough nutrition and decent medical care and
schools in order to fulfill their genetic potential for positive traits. And height, I've used
as an example because it is very uncontroversial, but we could apply the very same analysis to
intelligence, general intelligence. Now, there are people who argue about do things like IQ tests,
really measure anything real.
And there's been a lot of fighting
in the scientific literature about this.
But I think intelligence tests aren't perfect,
and they are sometimes culture bound.
But they are actually quite predictive
of later success.
And much more so than, say, SAT tests or GRE tests or MCATs
or other standardized tests. It presumably those correlate in some way.
They do, by do, but the IQ tests are better, actually.
There's a thing about the classic IQ test. I am talking about the modern variance
of the classic IQ test that are administered
by trained psychologists and aren't just a paper form.
And so they're not perfect and no test will be perfect,
but they're pretty good.
And so then if you ask the question,
well, what is the heritability for IQ tests score? Well, the answer tends
to be different depending upon the population. If you look again in countries like the
U.S., or in Western Europe that are fairly affluent, where people tend to have good access to nutrition and medical care and schooling
and kids get to play and they're not traumatized by a war. Then IQ test score is
heritable in the ballpark of 60-70%. But if you look at people who don't have those benefits who are poor, and this
can be in the United States as well, if you look at communities that face discrimination
and have consistently poor healthcare in schools, then IQ is lessitable. Why for the very same reason that it is in heights?
Because people can't live up to their genetic potential when they don't have
the basic things that everybody needs. So presumably if two identical twins, and
I realize they aren't identical, but you're familiar with twins. You have twin children.
If two identical twins are raised separately, the correlation in their IQ can only,
is it that only 60, I think you said about 66% of their IQ can be predicted on the basis
of their genetic makeup alone. I mean, it makes perfect sense to me as to why if one of those twins went to schools that
were demanding of, you know, a lot of different topic matter, and the other one went to schools
where the instruction level was really deficient that one would perform far less well on
an IQ test. Unless, of course, the IQ test isn't tapping into school-based knowledge.
It's tapping into some other thermometer of, so-called intelligence or IQ.
Well, you know, the thing is that good schools correlate with many other things, right?
So the students that go to good schools aren't just benefiting from good schools.
They tend to also have good medical care
and safer, less traumatizing neighborhoods,
and they're more likely to have parents
with books in the home and a whole number of things
that are all beneficial.
So when you try to do epidemiology on this,
you have to be aware that things are very deeply
interconnected,
but you bring up a good point.
So it turns out that the way we get these estimates of heritability, there's two ways.
One way is to compare so-called identical or monosigotic twins with so-called fraternal
or dizygotic twins. So the identical twins will share nearly 100% of their gene variants, and on average,
fraternal twins share 50% of their gene variants.
And generally speaking, when people do these studies in order to avoid confounds of sex, they'll compare same sex for
turnal twins, so boys to boys and girls to girls. And when you put these incidents into a formula
called Fisher's Equation, then you can come up with an estimate of the heritability of the trade. But there is an assumption present in that,
and it's called the equal environment assumption. You're saying, well, two kids raised in the same
family have the same environment. Well, that's not always true, right? That can be violated by a number of different situations.
It turns out that a more powerful but much more difficult way to estimate heritability
is by looking at twins' rear-to-part, either identical twins or fraternal twins' rear-to-part.
There was a landmark study called the Minnesota Study
of twins Reader Depart, which is abbreviated MISTRA.
That is really the gold standard for assessing the heritability
of many different human traits, both behavioral traits,
but also disease incidents.
But of course, it's a small M because the population
of identical twins, rear to part,
that you can get into the lab isn't that large.
I don't remember the exact numbers,
but they had something like 80, some identicals
and 50 some fraternals in their sample.
But by doing this, they were able to come up with a lot of interesting estimates.
And so, for example, most personality traits, what the psychologists use the acronym Ocean to
mean, openness, conscientiousness, empathy, agreeableness, and neuroticism. I think I got that right.
That's what it's meant.
Spelled right.
That these traits on average tend to be about 50%
heritable.
And so, okay, you say, right, well, 50% of those
personality traits is heritable.
The rest is gotta be like how you were raised.
It's gotta be in your family.
And so everyone was shocked when they actually did the analysis
and found that family has almost nothing to do with it.
And what are you kidding?
It's got to.
And I think the important thing to realize
is these traits I just listed,
we call these personality traits,
but they are not the sum total of the way you are
in the world.
Parents can inculcate many things in their children.
They can demonstrate traits.
So people are much more likely to go into an occupation
if their parents did.
They can inculcate moral ideas and religious ideas, but in terms of these ocean personality
traits, they have astonishingly little to do with it.
So then this brings up the question, well, if 50% of the variation in these personality
traits is not from your genetics and it's
not from your family, where does it come from?
And the answer seems to be is that it comes from the random nature of the development of
the body and the nervous system.
And this is a point that I think many people don't understand.
This is something that biologists know,
but we've done a very poor job of communicating
to the general public.
The genome, all your DNA, all three billion bases of DNA,
all 19,000 or so genes in a human,
don't make a blueprint for making your body and brain.
It's not a schematic diagram that connects everything
to everything, particularly in the nervous system
where we have these hundreds of trillions of connections.
Rather, it's a rather vague recipe.
So the genome doesn't say, oh, okay,
you glutamate using neuron in the brain region
called the phalamus, you know,
grow for 200 microns towards the top
and then cross the midline
and then grow towards the ear for, you know,
another distance.
No, it says something like,
hey, you bunch of glutamate neurons
in the phalamus over here in this area about half of you cross the midline. And so what
does this mean in terms of individual variation? Well, it means, well, for for some
individuals, 40% of their axons will cross the midline of the brain. And for
another individual, 60% will even in identical twins, and as you correctly said a moment ago,
identical twins aren't really identical, either in their bodies or their temperament.
So if you take newborn identical twins and you give them a CT scan just to measure the
shape of their organs, they're not the same.
You might have one twin who's spleen is 30% larger than the other twins,
or whose liver is 30% smaller than the other twins, even though they have the exact same DNA,
and they were lying right next to each other in the womb, and presumably had the same or very similar
fetal environment. And the reason is the random or as we say stochastic nature of
neural development. A great way to study this is with nine banded armadillos. I know we're getting
weird here, but I love the armadillo because I've been told tell me I don't want to
interrupt you too long, but as far as I know, the only animal in North America
that carries leprosy, that is true.
And there's a lot of twining going on in armadillos, right?
Well, what there is is actually quodding.
So armadillos, or the nine bounded armadillo in particular,
and they're different armadillos.
I'm not really an armadillo specialist,
so I don't know if this holds for all of them,
but the nine bounded armadillo is born
as identical quadruplets.
Awesome.
Awesome.
You can take these identical quadruplet,
newly born armadillo.
I don't know what you think you'll call them, pups.
I don't know what a baby armadillo is called.
I'm sure there's some particular word for it.
And someone will tell us,
I'm sure someone will tell us.
In the comments on YouTube,
what is the name of a baby armadillo?
I know like a ferret, baby ferrets are kits.
The moms are jills, the dads are bobs,
I used to be obsessed with this kind of naming,
it's a business of ferrets or what is like a gang
of raccoons or whatever.
So if you can tell us what the name is for the baby armadillos, as well as what do you
call a group of armadillos, you win the pride associated with being right.
That's right, right.
One of my favorites is on an ostentation of peacocks.
Amazing.
Or a murder of crows who comes up with this die.
I know. It's a good raft of otters. I. Or a murder of crows who comes up with this. Yeah, I know. It's a good
raft of otters. I think that's correct. So if you have four newborn identical nine-banded
armadillos, then this is a great model system that biologists can use to study stochastic
differences in development.
And sure enough, their brains are wired slightly differently,
their bodies are slightly different.
If you test them behaviorally, even very, very early in life,
they have different propensities.
Some are bolder, and it'll explore more.
Some are will tend to hide in the corner more.
And we know this from the lab.
You get a box of mice that are in bread from the breeder,
and you pluck them out, and they're not behaviorally identical.
Some might try to bite your hand, some will run away,
some will stand stock still.
Where does this behavioral variation come from
in mice that are nearly genetically identical?
Well, it comes from a bunch of things.
They don't always have exactly equal experience. But mostly it comes from a bunch of things. They don't always have exactly equal experience,
but mostly it comes from the pseudo-round-em stochastic nature of development.
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And is the pseudo-random stochastic nature of development, one of the major, excuse me,
driving forces
for evolution.
Because, you know, we hear about mutations and we always think, or people tend to think
rather, that mutations are bad.
But of course, mutations provide the variation that can also subserve adaptive traits.
I mean, if you're a fan of the X-Men, as I am, a huge fan of the X-Men, the entire series,
every single one, including the Wolverine movies,
you quickly come to learn that genetic mutation is at the heart of variation, which is at the heart
of individuality, which is what we're talking about. Right. And so genetic variation is at the
heart of individuality, but there is also, there are also these other things, right, that we've
talked about. There's the effects of early life experience,
and there is the stochastic nature and development,
because if you through the randomness of development
happened to have like a particularly great liver,
you're not gonna pass that on to your children, right?
That isn't in your germ line.
You won't pass that trait along.
Just a brief insert here on germline.
We had Oded Rusch-Jaffy on the podcast
who studies epigenetic transmission
and inheritance of, it's not Lamarkeyin,
we have to point that out,
but inheritance of sort of acquired traits does happen.
And the germline is the genes that are present in the sperm
and in the eggs.
All the other cells of your body have genes, of course,
but the best way to put this is simply going
to the gym and getting fit does not make your children
more fit because the germ line, as far as we know,
is not modified in a direct way.
In other words, the DNA within sperm and eggs
are not modified according to your behaviors
in most but not all cases.
That's right.
And as you correctly said about Odeod's work
and other people's work,
there is what's called transgenerational epigenetic inheritance,
which means that you can have traits that are passed not from
one generation to the next, but even two generations to the grandchildren that don't require modification
of DNA. But to date, that has been shown very convincingly in in a worms and in plants. The evidence
in mammals is is really not there yet in my opinion.
And most of the claims for that,
and it's a very popular thing to say,
I epigenetically inherited my grandmother's or great grandmother's trauma.
The evidence at present is poor.
Actually, a lot of it comes from epidemiology, most of which came from famines in the
other colleagues region of northern Sweden, and they had very good medical records, and they
said, oh, well, if your grandfather went through the famine, then you're more likely to
have this trait of your male, or if your grandmother went through this, then if your male
have this trait, and your female, that trait.
And I mean, there are two problems.
One is that there's not a biological mechanism, but the other problem is that the way these
things were discovered is by something called heart game or hypothesizing after the results
are known.
They did very many statistical comparisons to try to find something to
significant. And you know from your work in the lab that when you do many comparisons, you're
going to get some things that look significant just occasionally, randomly, through luck.
And you have to apply a statistical correction called a Bonferoni correction when you make many, particularly post-hoc
comparisons after the experiment, comparisons to set the bar
much higher for accepting that data.
And most of those studies, they didn't apply that correction.
And I remain unconvinced of transgenerational epigenetic inheritance in mammals.
Now let's be clear, just because it hasn't been shown convincingly now, it doesn't mean
that it won't be.
There are some good people working very hard on this, and they may well describe a mechanism and show this convincingly in the years to
come.
But right now, you may well inherit your grandma's or great grandma's trauma, but you're probably
doing it socially, not through marks on your DNA that changes how your genes are expressed
or not expressed. Yes. So I subscribe to the idea that there is absolutely, certainly, transgenerational
inheritance of parenting and upbringing, right? I mean, your grandparents raised your parents
who raised you. Not always people can be adopted. In fact, I have adopted members of my family.
But by understanding what you're saying correctly. The evidence that, for instance,
some stress-related gene was modified during a trauma
in my grandparents or great grandparents,
and the idea that that was passed to me
through my parents, that the evidence there is far weaker.
Right, and when you think about it,
well, like how did that happen?
That had to get into your, your grandparents sperm or egg cell and then produce that effect in the brain of your
parents, and then it had to get into their sperm and egg or egg cell and then contribute to producing it
in you. But, but fragmentation of DNA and sperm is, or in eggs is a common thing, especially as people age,
DNA, sperm and eggs fragment. And it's possible that some of those mutations still allow for
viable embryos. So it's in theory that germline could be changed by environmental events.
Well, right. But now I think you're starting to talk about things
that are heritable, right?
You're not talking about Marx on DNA.
You're talking about the structure of the DNA itself.
And that is its own separate issue.
Now, I think I want to be really careful about this
because what is now, I think, fairly well-established
is that you can transfer things epigenetically
over a single generation if, as a result of experiences that during the 1918 pandemic flu, many women were pregnant and
got the flu.
And if you look at their children, you find interesting statistical anomalies.
And those children, for example, the males wound up going into the army for World War II.
And of course, the army does a complete physical and the records are very good.
So you can go into that database.
And you find that the male children that were in utero during the winter of 1918,
during the pandemic flu, are on average a millimeter or two shorter.
Anyway, say a millimeter or two, that's nothing.
But in a huge statistical sample of millions of people,
that's enormously significant.
More interesting is that the incidence of schizophrenia
went up about fourfold from about 1% to about 4%.
And even though autism wasn't a term in 1918 yet, I don't think came along later, what we now retrospectively would call autism also went up by about 4
fold. So there's something about mom being stressed and carrying the fetus at a particular stage that seems to impact
brain development in a way that then makes that child more likely to be schizophrenic
or autistic when they grow up.
Do we know that it's stress?
And my recollection of this, I believe this was the late Paul Sternberg's work as well. I maybe have that name incorrect, but in any event, that it is, if pregnant mom gets the
flu in the first trimester, you see this higher incidence of schizophrenia and an autistic
offspring.
But do we know that it's stress per se?
Because it's stressful to have the flu,
but the flu is a bunch of other things.
It could be fever.
It could be some breakdown in the immune barrier.
I just want to open up the number of variables that this could be.
Or do we know that it's something in the
hypothalamic pituitary, so-called stress axis that is adrenals,
so hypothalamic pituitary adrenal axis,
is it elevated cortisol,
or could it literally be an immune neural interaction
of some other sort?
It's probably the last thing you mentioned
in an immune neural interaction.
And the reason I say that is that Gloria Choi at MIT,
together with her collaborators,
has made a mouse model of this phenomena.
So she takes pregnant female mice, and she
injects them with something that it's, she doesn't actually
infect them with virus.
She puts a chemical in that is on the code of viruses that
mimics viral infection.
And then what happens is that in a way that interestingly
is an interaction with the bacterial content of her gut,
produces a surge of a immune signaling molecule
called interleukin 17.
Interleukin 17 can pass through the placenta into the fetus, and if it's present,
just as you said at a particular point in development, it doesn't work anywhere during
pregnancy, but during something that is sort of the mouse equivalent of the first trimester,
if that occurs, it causes disorder development of the layers of the cortex.
Instead of looking like layers of a cake, you see balls and clumps of cells.
And parenthetically, in some, but not all post-mortem tissue from autistic people, you can also see
those balls and clumps of cells.
Those balls and clumps of cells thought to reflect alterations in cell migration?
They are. Yeah, some I don't know if it's entirely known how much of it is cell division
or migration, but certainly migration is a part of it. And it's very likely that that critical moment
to disrupt this ordering of the brain and produce these increases in schizophrenia or autism
vulnerability are coming at a point where neurons are migrating during development.
And so what choice group did is they did all the things you would want to do as a biologist.
So they gave things to block the function of this interleukin signaling molecule and it blocked the phenomenon. They artificially
injected the signaling molecule into fetal brain when the mom hadn't been stressed and they could
reproduce it. So I'm not saying that there aren't effects of stress hormones from the
effects of stress hormones from the hypothalandic pituitary axis that are important that you mentioned,
but in this mouse model system work, it seems that you can produce it through this immune signaling pathway. And so then the question is, well, like, are these mice autistic? Well, how do you know if a mouse is autistic?
And the answer is it's actually a little vague, right?
There are behaviors that neuroscientists say
are analogous of human autism.
And one of them is if you give a mouse a marble
in its home cage, it will bury it over and over again
compulsively or bury many marbles.
And people say that that is somehow analogous to some of the compulsive behaviors,
you see analogism. It's a bit of a stretch, right? I mean, it's a challenge to interpret
mouth behavior in human terms, but it's a reasonable first step.
It's a reasonable first step. Incredible.
I hope more will continue to be done as it surrounds the first trimester influenza hypothesis,
because it's been around a while.
Obviously, there's a spectrum of what we call autism, mass burgers, and nowadays people refer
to it as sometimes as as neuroatypical.
There's some high functioning people with autism,
there's some low functioning people with autism,
and for that matter, there's some high functioning
and low functioning people who don't have autism.
So, but it is something that I think demands our attention
and that hopefully will be resolved at some point,
because also influenza's
but one immune
insult and
Presumably pregnant women are being bombarded with all sorts of
viruses and bacteria and
fungal infections and fighting them off or not fighting them off and who knows what the variation in
neuroimmune interactions exist in there that give rise to,
you know, good variation and let's call it, you know, debilitating variation.
Well, that's absolutely right. And so for one example is that we don't know what the effects are on the children who were in utero while their mothers were
fighting off COVID, right?
We won't know for a while.
Or the home in cold.
And there might, I mean, there might be nothing.
Or there might be something serious lurking there like there was for a pandemic flu and will be very interesting
and important to find out.
Agreed.
I'd love to talk with you about mind-body, but before we do that, I would be totally
remiss if I didn't ask for your broad top contour understanding of the mini-brain, the
cerebellum, the so-called mini-brain. And here's why. I've been a practicing neuroscientist
for, you know, close to three decades. I know where the cerebellum is. I've dissected a
bunch of them. I could tell you where a few things are in there. I certainly have
read about what the cerebellum does. But whenever I do a PubMed search on cerebellum, I see an ever-expanding
set of things that the cerebellum is implicated in, not just balance. This must be here, but also timing.
Also cognition. I hear about timing in particular of motor behavior,
but then I also hear that it's involved in learning
and not just motor learning,
and it certainly is involved in motor learning.
Perhaps that little mini brain is doing 50 or 1000
different things, but how should we think about the cerebellum?
What is it doing?
And what are some of its core operations that inform both what it's doing and perhaps
what other areas of the brain are doing as well?
Because I can point to the retinas or to auditory cortex or to the thalamus.
And yes, there's some mysterious nuclei in the brain.
But to me, the cerebellum is one of the most cryptic and complicated structures to understand. And I know you spent some time in there. So what's the cerebellum is one of the most cryptic and complicated structures to understand.
And I know you spent some time in there.
So what's the cerebellum do?
Well, cerebellar researchers like to joke that the cerebellum is a counterweight to keep
your head from falling forward.
Oh, perfect.
Well, with all the texting nowadays, people need bigger cerebellum.
That's right.
That's right.
Probably over many generations then that will happen along with the expansion of the thumbs.
So, but of course everybody is gonna text with their mind in about another 10 years, right?
You'll have your lungs implant and you won't need your thumbs at all.
Yeah, or maybe just five or my friend Eddie Chang
is a neurosurgeon and works on the auditory system.
He's been on this podcast before he was saying that if,
in theory and actually in practice,
you could just record the neural output
to the muscles of the speech system essentially.
And you could just amplify that
and you could text without actually speaking.
In fact, when we read, he told me,
we are actually receiving the signals
as if we were going to speak the words we're reading,
but they don't quite arrive at the place
where you could get a full-blown post-anaptic potential
so you're not actually moving the vocal machinery.
So that means the motor signals are getting sent out there
and so you're speaking what you are reading
but you just don't know it.
That's right, it's very analogous
to what happens during the REM phase of sleep, right?
When you have commands, your brain is issuing commands to your muscles to do things, like
behave in your dreams, to run away or go here or go there.
But those signals actually are blocked in the brainstem and prevented from reaching your muscles
because the nerves that don't go through your brainstem
like the ones that control your eye movements
aren't subject to that block head.
That's why you can produce the rapid eye movements
in REM sleep.
But yeah, this is a general theme in the brain.
A lot of times you have the output, but then you shut it down. And there are REM sleep behavior disorders where people thrash and move
in their sleep during REM. And it's because this outflow that's normally blocked, isn't blocked.
Have you ever had the reverse happen? I have where you wake up and you're still in so-called rematonia.
You're still paralyzed.
Yes. And there's that split second that feels like eternity where you are wide awake and you cannot move.
And I'll tell you, it's terrifying.
Yeah, sleep paralysis and actually, you know, it's been known forever.
You can actually find ancient Greek depictions of people lying with a demon on their chest, paralyzing them,
and that is actually from sleep paralysis. Later Hogarth did a drawing of exactly that. So,
yes, there's a well-known phenomenon. But to get back to the cerebellum, as we started, so
as we started. So the cerebellum is, as you said, definitely involved in motor coordination. So people who have damage to the cerebellum aren't paralyzed, but they tend to be clumsy. They tend to
not coordinate their movements. They have a disturbed gate.
If they're reaching for an object, they often overshoot it and have to make successive approximating
motions to get back to their target.
So that's well understood.
But if you look through evolution, the cerebellum is connected to this brain region called
the phalamus, and it's connected from there to many regions, including
the frontal cortex where
Phanomena like like planning and
decision-making and
moral sense and many aspects of personality
sense and many aspects of personality seem to be encoded. So then the question becomes, well, that's very far away from being clumsy.
What are these connections doing?
And as time has gone on, I've been in this business from over 40 years now.
I'm an old guy.
And so initially we said, oh, yeah, cerebellum movement control, motor coordination, that's
what it's for.
As time goes on, as you correctly said, the cerebellum has been
implicated in more and more functions, many of which are far
removed from the motor system.
And if we're looking for a theme about what the cerebellum
does, is that it is there to predict the immediate future.
It's trying to determine what's going to happen in the next second or two to best guide
behavior.
As you can imagine, this kind of general computation could be applied very well.
You can see why it's important for you know, motor systems and doing sports and you know, if you're trying to hit a baseball looking at what
the picture is doing and trying to anticipate what the pitch is, but it also comes up in a social
realm. If we're trying to read someone and predict what they are going to do is this person
friend or foe, which is one of the first things that we try to assess when meeting someone. Are they competent, which is the second thing we try to assess when meeting something?
A lot of this depends upon predictive circuitry, and it depends in part on the cerebellum,
and it seems to be at least partially impaired in people who sustain cerebellar damage. So it seems as if interestingly, the cerebellum started out
for prediction related for motor control and through evolution, its basic computation has been
applied to other non-motor behaviors. Now, I'm speaking in generalities and a lot of the details of this remain to be worked
out and understood, but I would say that is in a nutshell the modern conception of the
cerebellum.
Thank you.
Finally, somebody explains to me at a top contour, but highly informed way what the cerebellum
does, I couldn't be more grateful.
My pleasure.
In all aspects of biology and life,
the term nature versus nurture is relevant,
but never so much as when thinking about the nervous system.
And I know this firsthand because I've
studied neural development, both the nature side,
the so-called hard-wired stuff that genes just
set up. Neurons wire up to that neuron, etc. The cerebellum is in the back, the eyes are in the front,
the hardwired stuff, and then the softwired stuff, the nurture stuff, is the stuff that can be
modified by experience. What are your thoughts on nature versus nurture, and should there even be a versus in there?
Yeah, I don't think there should.
I have a lot of problems with nature versus nurture as an expression.
It was popularized by Francis Galton in the 19th century, a colleague of Darwin's. And I think it's wrong in or misleading in a lot of ways.
So of course the nature in nature versus nurture is meant in this case to me in heritability, right? What you inherit in the gene variations from your mother and father.
And nurture means like how your parents or your community raised you. The problem I have
with nurture is that it is too narrow a term. That really, it should be replaced with the word experience and experience in the
broadest possible sense, not just social experience, but the foods your mother
ate when she was carrying you in utero. The diseases you fought off or your mother fought off while she was carrying you in utero,
the bacterial population of your guts. So experience meaning anything that impinges on you,
starting from the earliest stages of fetal developments, continuing to the last day of your life. I think it should be very expansive, much,
much more than social experience in the family
or the community.
And as you mentioned, I have a problem with a versus
because there's this idea that these things
are essentially in opposition.
Well, is he that way because of his gene variance or is that way because
of what happened to him? And I think the thing to realize is that experience and heredity interact
in all kinds of interesting ways, some of which are oppositional and some of which are
reinforcing a classic one from genetics has to do with a genetic disease called phenolkyteneria or PKU,
which is an inability to to metabolize the dietary amino acid fennel alanine.
And so in order to have this,
you have to inherit broken copies of this gene
from both your mother and your father.
So it's a so-called recessive trait.
And here's where the experience comes in.
It only matters if you eat foods rich and feral alinein.
If you don't, it doesn't matter that you inherited these things.
Right?
So that's a way which genes and experience interact.
And the idea of ways in which they interact positively, think about athletic ability.
So a lot of athletic ability is, has a heritable component. If you are born fast,
for example, then you're more likely to do sports and practice them and get better at
sports as a result of your experience. So here, genes and experience are feeding back on each other in a positive feedback loop.
So there really isn't a versus at all.
And then, of course, the last thing is that this isn't the entirety.
So we talked earlier about the pseudo-random nature of development, stochastic development.
And so if I were to take the phrase phrase nature versus nurture and reconfigure it,
I would change it to read heritability, interacting with experience filtered through the random nature of development.
Now, that doesn't fall off the tongue as elegantly as nature versus nurture. You know, nature versus nurture is like,
if the gloves don't fit, you must quit.
You know, it's got that kind of snappy, snare drum beat.
But I think it's a more accurate.
So heritability, interacting with experience,
filtered through the randomness of development.
Yeah.
So we can shorten that up and we'll just call it the linden hypothesis.
You know, I don't think I can take credit for that.
It belongs to other people.
Sure, but there's a long history and science of things being shortened up and coined.
And that's as important.
I'm not, we're not trying to rob attribution here.
And the good news is, perhaps you can't call it the Linden hypothesis, but I can.
All right.
And what I've found is as with the GALP in equation, which is now out there as a hydration,
it's a formula that gives broad, but research informed parameters as to how much water one should drink in order to maintain proper hydration for physiologist Dr. Andy Galpin, who's a physiology and an expert in all aspects of exercise science.
There's the Galpin equation. There's the sobered principle. So I'm naming these things left and right, where appropriate. And so I'm naming these things
sparingly and where appropriate.
So from here on out,
heritability, interacting with experience, filtered through the randomness of development
as the linden hypothesis, and I'll be damned if anyone's going to rename it
faster than I'm gonna propagate it.
So, all right. Well, I think all the the geneticists will be gnashing their teeth
about this being named after someone who isn't actually a geneticist. Quite all right.
And their dentists will thank me. Let's talk about mind body. Okay.
I'm fascinated by this for a couple of reasons and I promise to keep this brief
But when I was growing up I was very interested in animals and biology and my father's a scientist and I got very interested in neuroscience early
as people perhaps know and
So much of neuroscience as I was coming up through the mid 90s
2000s 2010 to 20 stretch,
which focused on the brain piece.
Very little on the body.
There was nothing about gut brain access
in the early discussions and coursework.
In parallel to all of that, I've been interested
in mental health, physical health,
and let's just call it performance
and got interested in meditation,
respiration-based practices, things like yoga,
knee-dra, things that, by way of experience, I understood immediately had a
profound influence on the nervous system, states of mind and body. Nowadays,
there's an entire institute at the National Institutes of Health for
complimentary health and medicine, essentially exploring things like yoga
knee-dra, respiration practices, even supplements
and things of that sort.
And there's this understanding that, oh my goodness,
the nervous system extends into the body
and the body sends neural signals back into the brain.
And so this whole notion of mind body
has fortunately migrated away from California counterculture,
migrationally migrated away from California counterculture, Estonian Institute only, you know, hippie, new age, magic carpet,
stuff, by the way, that's not what I believe,
that's often how it was looked at in the past.
And now people at every level of science and medicine,
at every major university and in
every scientific journal are starting to publish papers about the interactions between bodily
organs, like the breathing apparatus, the diaphragm lungs, the heart rate variability we hear
about, deliver the gut brain access in particular.
And so mind body, the idea that our thoughts could influence
our body and that our bodily state could influence our thoughts is fortunately not just understood,
but it seems to be both accepted and appreciated. So what are your thoughts on mind body? What
does that mean to you? And what do you think is the potential of the mind body
interaction? It seems to me we've just barely scratched the surface. Yeah well I'm glad you asked
because I think it's a really fascinating situation and where things are changing very, very quickly. And I think to me, the most important thing for people to understand is that when you have a hypothesis, let's say you have a hypothesis
that meditation can attenuate chronic pain. All right? Well, there is a temptation to think that this operates outside the realm of science and
biology.
That is in some very very realm and the clouds that this happens.
And I mean, for good reason, there are a lot of people who will describe it in exactly
that way with auras or they
clop scientific terms like resonance and energy, but they don't actually use them in scientific
way.
So, you know, there's a lot of very fuzzy language that surrounds this, but it shouldn't
obscure the fact that when you have a hypothesis that say some mental state, like meditation or guided breathing,
affects some process in the body, that you should be trying to understand this in terms of a
biological hypothesis, not in terms of some indistinct realm that is different like manifestation.
Yeah. I really learned this initially from my father.
My father was a psychiatrist,
in fact, a talking cure,
old-fashioned psychoanalysts, how does practice in Los Angeles.
And we would have dinner together,
everyone's in it.
And he would always tell me about his patience.
He was very careful to keep confidentiality,
or he wouldn't break confidentiality.
But, you know, I would say, oh, yes,
how's your narcissist, oh, we have this dream.
So this was normal conversation when I was 14, 15 years old
with my dad.
And one day I said, dad, it's really clear to me
that through this talking cure, a large fraction
of your patients feel better.
And they conquer their depression or their obsessive thoughts
or things that are blocking them.
How do you think it works?
And he says, well, we don't really know the mechanics,
but ultimately, when it works,
it's not working in some area of ferry realm,
it is working by changing the biology of the brain.
And when he said that,
it was like a lightning bolt went off in my head.
And I thought, well, I don't have the kind of personality
to be talking cure psychiatrist. I'm not nearly nice enough. But I could understand the underlying
biology. Maybe I'll do that. And so, as you've correctly pointed out, when you say the phrase mind body, you're talking about
two directions.
You're talking about mental functions affecting the body, and then you are also talking about
how phenomena in the body affect the mind.
And we're understanding so much more about how that happens.
And I think the general thing for your listeners
to appreciate is that we have some culprits here,
and generally speaking, there are two classes
of culprits.
So if you want to get signals about body to the mind,
there's two ways to do that.
One of them is through neurons that reach out into the body
and sense things.
And this is referred to as interoception, right?
So as opposed to extra-oception,
you're outward pointing senses.
These are the senses that monitor your own body.
And while we can
consciously be aware of a lot of that information, a lot of it is happening subconsciously.
Like, your breathing is happening automatically most of the time without you thinking about it.
And that depends upon sensors about your blood chemistry and the state of your lungs and a number of other things that are regulating
that process and it's all happening in the brain, usually below the level of your conscious
attention. In addition to the neural signals, there is also a whole realm of hormonal or diffusable
immune signals.
And what these are is that these are chemicals
that are released into the bloodstream
and that move throughout the body
and that can activate neurons in the brain
or in other parts of the nervous system
to produce changes in mental function.
And I think the real thing that is exciting a lot of people right now has to do with immune
signaling molecules.
So there's a class of molecules called cytokines.
And cytokines are basically the signaling hormones of the immune system and they can flow
through the bloodstream and through lymphatic fluid and reach
many parts of the body. We've known for a number of years that the specialized receptors
for the cytokines are found throughout the brain and yet we know very, very, very little about
little about what they do. And that's going to be an astonishingly fruitful area of scientific research. But to give one example, there are a lot of things these days suggesting a link between inflammation in the body, whether it be a mungot or in other places, to depression. Well, how might that work?
Well, it could work either through inflammation sensing neurons sending electrical signals
to the brain, or, and it's not either or, it could be both, it could be
immune signaling cytokine molecules
produced at the site of inflammation
that then travel through the bloodstream
and the lymphatic system to then reach the brain,
bind receptors, and have effects.
And so one of the mysteries about depression
is that it's not that tractable to pharmacological therapy.
So if you look at people who suffer with depression,
about a third of people see significant benefit
from modern SSRI and related antidepressant drugs,
about a third see very tiny benefit
and about a third see no benefit at all.
And part of the reason is because maybe our term depression
is too big a bucket.
Depression is actually many different biological disorders
and only a subset of those are helped by SSRIs
and we'll need different therapies for the other ones.
That's certainly part of it.
But part of it might actually have to do with inflammation.
So if you think that inflammation is a risk factor
in depression, well, you could do something very simple,
you could gobble and ibuprofen.
There's a whole bunch of anti-inflammatory drugs
that are very well understood.
And so, well, what if you just say, all right,
you know, let's have a study where we have a bunch of depressed people
and we have them all eat anti-inflammatory drugs for a few weeks and we see
if this relieves their depression. And the answer seems to be, no,
it doesn't. Well, and that's a little bit hard to understand because there are
definitely links between
inflammation and depression.
So for example, one of the early treatments for hepatitis C that since been superseded
by more modern drugs was a pro-inflammatory cytokine molecule.
And when you gave it to people to treat their hepatitis C, almost everyone
became depressed on the stroke.
So, oh, well, this really seems like a link.
Likewise, there are certain neurological diseases like multiple sclerosis.
It turns out the incidence of depression as a comorbidity in multiple sclerosis is enormous.
And you might think, well, there's a trivial reason for that.
If you're paralyzed from MS, you're bummed out about life, and that's the reason.
But if you look at people who have spinal cord injuries from accidents, they actually have
major depression at a rate from people who are uninsured.
So that doesn't seem to be it.
It's not just that you're bummed out from being paralyzed, although of course it's reasonable to be bummed out
about being paralyzed, but that's not it.
So what happens in MS?
Well, there's a bunch of cytokines,
including one called interleukin-6, IL-6.
That's elevated massively if you take a spinal tap
and you look at cerebral spinal fluid.
And so that could be causative for depression.
So all these real reasons
to think that inflammation is involved, but yet the idea is still a little messy. So now what,
if instead of looking at the general population of depressed people, you look at the subset of people
that don't respond to SSRI antidepressants, are they helped by anti-inflammatories? And there's a bit of a hint that maybe
they are. It's not definitive yet. There are a couple of studies. It's right on the edge. But I think
this is a really good example of how we are going to see progress very soon in the body to mind, part of mind body medicine, that
is going to be of enormous benefit to people.
So interesting.
Could I get your thoughts on one candidate hypothesis that I've been thinking about.
I've covered depression on a few episodes and I've had a Robin Cardard Harris from UCSF
and Dr. Matthew Johnson from your very own John Hopkins.
University both of whom work run laboratory
studying psychedelics for the treatment of depression.
The clinical trials on psilocybin and to be clear,
psilocybin is still illegal.
It's been decriminalized a few places,
but we're not talking about recreational use,
we're talking about several therapy sessions,
and then two, without psilocybin,
then two, 2.5 gram,
approximately, dosages of psilocybin
given separately, again, with therapist present,
and then follow-up therapy sessions
seem to lead to relief of depression
in approximately somewhere between 65 and 80% of people,
in some cases total remission,
in some cases some relief without remission.
Okay, so we can kind of set that result on the shelf.
It's been repeated a number of different times.
Compare that to the results of SSRIs,
which seem to help a third of people,
a third minimally, and a third
not at all.
And of course, there's a side effect profiles of the SSRIs and associated drugs, not just
the SSRIs, but reprieron and the other antidepressants that are taken in prescription drug form.
And then there's this inflammation piece.
So could we hypothesize that relief from depression has something to do with neuroplasticity, rewiring
of neural circuits.
And that psilocybin, we know, can encourage neuroplasticity.
And that perhaps SSRIs can encourage neuroplasticity in some people, not all, and that inflammation
is a barrier to neuroplasticity.
To me, this is the only thing that can reconcile the current status of the results.
And then there's ketamine-based therapies, and so we have to also kind of set that on
the shelf.
But let's set that aside on the shelf for now to keep it simple.
It seems to me that based on the time course over which SSRIs work, the fact that they
increase serotonin very quickly,
but the really from depression comes from much later.
The fact that neuromodulators like serotonin
are intimately involved in neuroplasticity,
they can in some cases, gate neuroplasticity,
that it all centers back to changing neural circuits.
And so what we're really trying to do,
whether or not it's transcranial magnetic stimulation,
or now we can throw ketamine in there,
or psilocybin or SSRIs,
is that treating depression is about rewiring the brain. magnetic stimulation, or now we can throw ketamine in there or psilocybin or SSRIs, that
treating depression is about rewiring the brain.
It's not about chemical A or B per se, although serotonin seems involved.
To me, what I'd love to see is our more studies about the interaction between neuroplasticity
and inflammation.
And are we seeing that kind of work out there? And because these
results sort of sit as disparate, somewhat conflicting, but it seems like inflammation is anti-nuropleasticity
and broadly speaking here. I realize there are many interleukins, there are many, I know, some of which
are inflammatory, some of which are anti-inflammatory, but is that a meaningful hypothesis? And
But is that a meaningful hypothesis? And do you think there's any hope whatsoever to actually cure depression if we sort of start to
unify the results in these different camps?
Yeah, I think it's a completely reasonable hypothesis, and I would be broader.
And I would say honestly, the relief of any neuro psychiatric condition ultimately is
from neuroplasticity in some form or another.
And I think it's worthwhile to step back a bit
and talk about what neuroplexicity means.
To date, there has been a focus on synapses
on the contacts between neurons as the site of neuroplexicity.
And that's warranted. Synapses are plastic. They change as a site of neural plasticity. And that's warranted.
Synapse is our plastic.
They change as a result of experience,
as a result of hormone changes,
as a result of exercise, as a result of lots of things.
But synapses are not the be all and end all of neural function.
So for example, neurons work by sending electrical signals along their lengths
and between neurons and interconverting those chemical signals. And the processes of generating
those electrical signals, the ion channels that are involved, that are embedded in membranes,
that are involved in that are also plastic. They can also change as a result of experience.
That's what we call intrinsic plasticity
as opposed to synaptic plasticity.
In addition, there are literal morphological changes.
So when we talk about the wiring of the brain,
sometimes we're talking about literal wiring,
like cell A wasn't connected to cell B,
and now it is, and that changes.
And then sometimes, well, actually, cell A was connected to cell B, but cell B wasn't
responsive enough, and now there's a change in cell B. So now cell A can fire cell B.
And that could have been a result of a change in its synapse, making it more receptive to
know a transmitter released from cell A, or it could be something intrinsic in cell A that
makes it fire its electrical signal, its spike more easily.
I think that one of the key cell types that's going to be important for your hypothesis
linking inflammation to synaptic plasticity is going to be a cell called the microglial cell.
And microglial cells are non-ironal cells in the brain, they're motile, they can crawl around,
they have long processes, and they can gobble things up. They can literally sort of chew away and digest bits of the extracellular scaffolding that surrounds neurons and synapses.
And thereby renders them plastic. They can destroy synapses.
And there is a lot of indication that certain disease states may involve over exuberant microglia pruning synapses to a degree that they shouldn't.
And we know that microglia are chock-full of cytokine receptors, and so are responsive
to inflammatory signals.
When we're talking about inflammation and we're talking about drugs, it's worthwhile to mention that there are a lot of
behavioral things that also can influence the signaling. So we know, and I know you've discussed
on your program, the incredibly solubrious effects of physical exercise on mental function. So
exercise is about as good an antidepressant as SSRIs are.
And the side effects are only good side effects as opposed to the bad side effects of SSRIs.
And again, this isn't working through some area-fairy realm.
The reason that exercise works to relieve depression and the reason that exercise works to maintain your cognitive function as you age is because
of biological pathways that we are now uncovering some of which will involve microleal cells
and neurons and other types of cells in the brains, some of which will involve not the neurons
in the brain at all, but the brain's vascular churn. So we know that exercise is very salubrious for keeping blood flowing to the brain.
And when you're young, you have a superabundance of blood flowing to your brain.
So it doesn't matter if it's reduced, transiently, you're fine.
But as you get older, your blood vessels become more occluded and less elastic,
and you're closer to the trouble spot.
And if you exercise regularly,
you can dilate and make your blood vessels,
including those in your brain more elastic,
and that is almost certainly protective against both depression
and cognitive decline as we age.
I am a fan of exercise, but I'm fortunate that I enjoy running in some forms of resistance training.
So I always assume that the good side effects were just the positive mood effects
until the recent literature that, as you mentioned, improved vascular, vascular
blood flow and reduced inflammation.
If not during the exercise when inflammation actually increases, decreases inflammation.
I'm delighted to hear you say the word microglia and my postdoc advisor, the late Ben Barris,
would be especially delighted.
People can look up Ben.
I'll provide a link to his biography in the show note captions because he really championed
to the point of, I don't know if champion's even a sufficient word.
I mean, Ben was beating the drum saying, we have to pay attention to Gleeo.
We have to pay attention to Gleeo for the longest time.
Gleeo were relegated to these other journals.
They even had their own journals.
And in the last, what is it, 10 years?
There's been a kind of explosion of research
exploring the role of microglia and other glial cell types.
And it's really fantastic to see that this,
actually the most abundant cell type in the brain
is the glial cell are getting the attention they deserve.
It's absolutely true.
And, you know, we scientists like to think
that we're very rational creatures
and we're not subject to fads, but we totally are.
Right? When I started out in this field
in the early 80s, everything was about opioid peptides.
And then there was a period where gaseous neurotransmitters
like nitric oxide were all the
rage. And you know, right now, Glyar in the spotlight, for a good reason, I'm not trying to say that
it isn't worthwhile. But there is this phenomenon of things being fatter and people jumping on
bound wagons. And it happens both in terms of the subject we study, but also in terms of the techniques
we use.
And right now, the technique that is most fattish involves single cell expression profiling.
That is creating a list of what genes are turned on and how strong they're turned on in single cells
and seeing how that changes in different cell types
and with experience.
And it's a very valuable technique,
but one could argue that it is perhaps a bit overused
on that 15 years from now, people will go back
and say, gosh, those folks in 2023
were really overdoing it with the single cell profiling.
And if anyone's thinking about getting into the field
of neuroscience or another area of biological
or other research, I can just tell you
that if you're starting your PhD or your postdoc,
take a look at whatever fat is happening now.
And just know that in five years
it will be something different.
And it takes you about five years
to finish your PhD or postdocs.
So pick something different than what's fatish now and you'll land right on the money.
But there's always a lot to do.
You don't have to do it.
Everyone else is doing it.
And indeed, the deletion test becomes relevant here.
The deletion test, as it was described to be by my colleague, E.J. Chicholinski at Stanford
is, if you look around and you see one or more groups doing what you
want to do very well, just pick something else.
Your life's going to be a lot more pleasant.
Absolutely.
I agree with EJ on that entirely.
Let's get back to mind body.
There are a bunch of different domains of mind body.
So aptly pointed out, it's bi-directional, mind informs the body,
body informs the mind. But we could probably break this down into respiration. So breathing,
conscious patterns of breathing, emphasizing inhales or emphasizing exhales,
cyclic hyperventilating, etc. could also be thought patterns.
A little bit harder to break those down, but many, not all, but many forms of meditation involve having a very still body,
not all, there's walking meditation, et cetera,
but still body focused mind.
Kind of a, not a state that we are in a lot of times
unless we direct that state.
There are still other mind body patterns of communication through very still body, deep relaxation,
things like yoga, knee, jaw, non-sleep, deep rest.
There's hypnosis, there's touch-based body-mind communication.
If we're going to talk about mind body, it also, we should refer to as body mind,
how do we dive in and think about this?
Because this is involving clearly
a thousand different neural pathways,
not just the vagus nerve,
it's typically people just kind of hang their hat on,
mind body must be vagus nerve,
and of course it involves the vagus,
but the vagus is an extensive set of pathways.
So how do you like to frame up mind body? And what's most intriguing to you about
mind body
communication both in terms of the biology and its practical applications?
Well, I think just as we talked about how there are two potential pathways
in conveying signals from the body to the mind, there are also two potential pathways, at least two, potential pathways, to conveying signals from the brain
to the body, and they are the neural signals that are conveyed
by neurons that actually get there, and they are hormones
and neurotransmitters and cytokines that are released
from the brain.
I should mention that hormones are actually produced
by neurons, including, for example,
some of the hormones that you think about
as being produced as sex hormones,
like estrogen is produced by neurons in your brain,
for example.
So, let me give an example that I think is a bit out there,
but I think is really, really fascinating.
And this comes from the cancer world.
And so melanoma is a bad cancer.
It kills a lot of people that can spread.
It's highly metastatic. And we know that melanomas often become
innovative, that is to say they become contacted by neurons and wrapped and receive signals
from them. And we also know that if a melanoma becomes innovative, then the prognosis for that patient is worse.
It's more likely to grow.
It's more likely to spread.
Well, how does that happen?
Well, recently there have been some reports
that show that neurons that innovate the melanoma
don't act directly onto the tumor cells. Rather what they do is they secrete a signaling molecule
that has a receptor on immune cells that are patrolling the edges of the melanoma tumor and nibbling away at it. And when that signaling molecule is released from the neuron, it shuts down
or reduces that immune patrolling function. And then as a consequence, the tumor can grow
and spread and butt off more readily. So this signal that comes from neurons is sending the ambulance's home,
so to speak. Yeah, exactly. And the signal is something called calcitonin gene-related peptide or
CGRP. I'm familiar with CGRP from the domain of touch and its involvement in, I think, like,
itch perception, itdwayne perception, itch perception. It do have.
Pain perception and itch perception.
All right.
Interesting.
Yeah.
And so, all right.
So, if neurons can affect the progression of cancer through their activity, and these
neurons in the periphery are ultimately connected to the brain
through a couple of different hops. Then, is it reasonable to hypothesize that mental processes
could affect cancer progression? So let's say we have a hypothesis and it's a wild hypothesis,
and I want to just emphasize that there is not
evidence for this, but let's make the hypothesis that says that through meditative practice you can
slow the
progression of
certain tumors that tend to get
Interfated, right? Well, right now this is just kind of
a wild idea, but I think the important thing
as I've said before, this is a wild idea
with a biological substrate. It's not like you meditate and
magic happens and force fields
open in the angel saying, and then your tumor shrinks.
This is, we are saying that activity
in certain areas of the brain is increased
by this meditative practice,
and that this sends signals to this neuron,
and this neuron that actually go to the tumor
and make something happen through this biochemical pathway
that we have defined.
And to me, this is speculative,
but it's also extraordinarily exciting. It opens a kind of investigation of mind-to-body mind to body, sickening, that has received very little attention up to now.
Incredible. And I say incredible because while you're giving an example of CGRP and nerve
innovation and metastatic tumors, I absolutely love the idea that a phenomenon involving some practice that could be put under
the umbrella of mind body or body mind becomes something entirely different when we're trying
to hang that on the hook of a biological process.
It's like something fundamentally changes there. Right. You know, it's amazing to me, for instance, that early on psychedelics and breath work, conscious
breath work, were lumped together, cost people their jobs at major universities.
I won't name the universities because you work at one, I work at another and there's
a third one called Harvard, I guess I just named them.
But nowadays, there are laboratories that every single one of those institutions studying
deliberate respiration on health, as well as psychedelics and meditation for that matter.
With the goal of understanding what cytokines, what neurotransmitters, etc., change through
defined pathways, including Vegas, but frenic nerves and frontal cortex and all the stuff that is considered,
you know, classic rigorous neuroscience. So I do think we've entered a new era.
So it's not costing people their jobs anymore. It's actually giving people their jobs.
And it's federally funded, which itself is also fantastic, in my opinion.
So we are in a new era.
What do you think needs to be done to really nail down the idea that
how we think influences our biology, even though it's a total duh,
because everyone knows that chronic stress, for instance,
can be detrimental, short-term stress can actually be beneficial.
But, and stress is a mental process
that essentially deploys chemicals in the body,
that then create other issues in the body,
that then create shifts in mental process.
It's so obvious when it's spelled out,
but it's just remarkable to me how this has just been lumped
in the category of like woo science.
And I can't quite figure out what needs to be done in order to convince people that their nervous system includes stuff outside the skull and spinal cord.
And of course, of course, of course think it is the job of biomedical researchers right now to reclaim a lot of this
from the realm of nonsense. And the problem is there has been a lot of nonsense. And
you know, there's sort of a visceral reaction. And when someone says, oh, yeah, well,
you can do breath work and it'll realign your chakras.
And that is what will reduce your anxiety or god inflammation.
And I'm tempted to just go, oh, shut up.
But what if the chakras are collections
of nerve innervation of bodily sphinctures?
It could make sense.
Right, it could, but there's gotta be some biology.
In some cases, these analogies are rooted in something real.
And in some cases, they're just made up bullshit.
Right?
And I think the challenge is to have really rigorous scientific tests of these things to take it back.
And to be willing to say, all right, there have been a lot of claims, for example,
made about how mental processes can influence the body.
And only a subset of those are going to be true, and of that subset, it is our job to
understand how they work, both to rationalize them, but also to optimize them and make them
better.
There's no question that mental processes affect the body.
We know, for example, that if we just keep you awake and don't let
you sleep long enough, you'll die. And what will you die from? You'll die from sepsis because
the barrier between your gut contents and your peritoneum will break down, right? Well, so,
how does that happen? Right? We're just starting to understand. Like,
there's a really dramatic example, but there are going to be many more subtle examples. So,
you've mentioned breathwork a couple of times, and I think this is really interesting.
My colleagues who are interested in respiration tell me that you can record in many different places in the brain,
many different places in the neocortex and in other regions,
and find a signature of the breathing rhythm,
sort of as a background to neural activity.
You can find it in the cerebellum,
you can find it in the frontal cortex,
you can find it in the cerebellum, you can find it in the frontal cortex, you can find it in the hubbenula, which is implicated in many things, including depression, you can
find it lots of places. So the idea that conscious modulation of your breathing could have manifold effects on neural function, I think is reasonable given that kind of observation.
Here, here. Let's talk about you a bit more. You've been so gracious in covering this wide array of
topics and with such eloquence. And I must must say I've been delighting in all of it.
You are in a unique position these days because if I understand correctly,
you've been diagnosed with a fatal illness. I suppose we've all been diagnosed with a fatal illness of sorts because
we're all gonna die sooner or later.
If you're willing, could you tell us the story of how that diagnosis came to be, what your
initial reaction was, and where things stand now, and perhaps we can explore some of the,
well, let's just say, pleasant surprises that have emerged since that initial diagnosis.
Well, sure, I'd be happy to.
So in the summer of 2020, in the dark days of COVID,
when things were looking really bad,
I developed profound shortness of breath.
I couldn't get up a flight of stairs without
without huffing and puffing and I thought, oh, well, I've got COVID, but I took COVID tests. And there was they they were all
negative. And I thought, oh, I must have COVID. I've got the
symptoms of COVID. I have respiratory issues. I'm feeling
weak. It's got to be COVID. And after a while, when this didn't
go away, my wife said, like, you got to go into the doctor. This
is crazy. It's you got to find out what's going on.
And I did.
And they hooked me up to an electrocardiogram.
And they said, oh, you've got atrial fibrillation,
meaning that your heart is doing two beats every time
it should do one.
So I have a very high heart rate.
And when the heart beats that fast,
it can't work very effectively.
There is enough time to recharge before the next beat comes.
Now, it turns out that there is a very straightforward therapy for this.
Atrial fibrillation comes from electrical signaling in the heart, sort of swirling about in a circle,
and reactivating part of a heart muscle faster than it should.
And so if you thread through a catheter in your groin up through blood vessels, you can
put in a little needle and use that to quadrize into a plate, a tiny little strip of cells
in the heart that will produce a barrier that will prevent that
aberrant return of electrical activity and will cure atrial fibrillation.
So I have that process, that ablation surgery, and sure enough, it cured my atrial fibrillation.
I was feeling terrific.
And they said, oh, as a follow-up, come back a few months later and we'll do an
echocardiogram to see how your heart looks. And they did, and they went, oh my God, there's this
huge mass pressing against your heart. It's like the size of a coke can. Here's what we think it is.
We think it's a hadle hernia. We think your stomach is poked up through the diaphragm muscle and it's nestling next
to your heart.
The way we diagnose this is kind of humorous.
They say, shug this can of diet, Dr. Pepper, and then quickly get up on the table and
we'll do the echocardiogram.
And in the echocardiogram, we can see a signature of the popping CO2 bubbles in your soda.
And if we see those in the mass, then we know it's your stomach.
So I did it, I chugged it, I got up there, oh, no, it's not your stomach.
I said, oh, okay.
Well, what we think this is is a teratoma.
And a teratoma is a developmental anomaly that you carry usually from fetal life,
where there's a group of different cells that gets in a place where it shouldn't during development
and then grows. You've probably heard about people who sometimes get like a tooth that grows hair
in their abdomen. Sometimes women have these around their ovaries. And they're not malignant.
They don't spread. It's a fairly easy thing. But I had this enormous co-can pressing on my heart.
It may have, we don't know, have been the source of my
atrial fibrillation to start with.
But in order to deal with this, I had to have open heart
surgery.
So I had the surgery, and it was a big hairy deal.
I was told it would last about five hours.
It turns out it lasted two days.
They had me on the heart lung bypass machine
longer than you're supposed to,
because you're very likely to throw a clot
and get a stroke, fortunately that didn't happen.
I had very skilled surgeons at Johns Hopkins.
It was bleeding so much that they couldn't close the chest.
So they had to do all the surgery
and then just leave me anesthetized with my chest open
until the bleeding stopped.
So the surgery was a bear.
And then I'm waiting to get the pathology report back on the tissue they removed and it came
back and it was bad news.
Sorry, it's not a teratoma, it's not benign.
It is a kind of cancer called sonovial sarcoma. And sonovial sarcoma is a moderately rare
cancer, and it usually affects the sonovium, which is the
lining of the joints, or some other places. It's pretty rare to
have it happen in the heart. There are a few examples. If you
look in the biomedical literature, for common cancers like testicular cancer or
breast cancer, there are huge tables of statistics from millions of patients on what's been
tried and what works and what the prognosis is.
For sonofial sarcoma of the heart, there are only individual case reports.
Oh, there's a guy in Kenya and he got it and this is what happened.
There's a woman in Minnesota and this is what happened with her,
right? There are no statistics because it's that rare. And the oncologist said, well,
I think you've got six to 18 months to live. Now this was about now 27 months ago. So I've fortunately exceeded that lifespan estimate. And I think
we got to be clear also that, you know, being an oncologist has got to be a terrible job
for many reasons. But one of them is that you got to give a lifespan estimate, even if
you really don't have the data to do it in a very informed, you can't just say I won't
do it, right? You got to do it. People expect it it in a very informed, you can't just say, I won't do it, right?
You got to do it.
People expect it.
So, you know, I'm not saying like, oh, the oncologist was incompetent because I've
helped live my estimate.
You know, he was trying to do something based on very little information made his best
guess.
So, you know, I got this information and I was furious.
I was so angry.
Hard cancer.
Who the hell gets hard cancer?
Is that even a thing I've ever heard of somebody with hard cancer?
No, until now.
Hard cancer.
What the f?
I've got hard cancer.
This is crazy.
Time I was 59 years old.
I got a lot to do.
I can't have a heart cancer. And what was, I think,
transformative for me is that at the same time that I was feeling a white, hot angry with
the universe, I was also feeling a deep sense of gratitude for what I've had.
I've had a terrific life.
I'm not that young.
I've had a lot of it.
And I had great parents, wonderful friends growing up.
I've had a good career.
It's been a fairly easy run of it. And I think the ability to have a job where
you follow your own curiosity every day, there's nothing like that. So few people in the
world get to live that way. I feel incredibly grateful. And I feel incredibly grateful to my family.
And I have a wonderful wife named Dina,
and she's just the best.
How do I deserve this?
I don't deserve her, honestly.
So, in neuroscience, we often think,
oh, well, you have a state, you have a set point,
are you anxious or are you relaxed?
Are you fleeing or are you approaching? It's like a set point. Are you anxious or are you relaxed? Are you fleeing or are you approaching?
You know, it's like a single axis. Well, but it isn't. You know, and I think most people understand that, but but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but, but and profoundly angry in the very same moment.
And having cancer and getting the kind of treatments, the chemo, the radiation,
it's famously deeply unpleasant. And I had all that. And it was just as unpleasant as anyone's
cancer story that you've heard, the radiation burned my esophagus. I couldn't eat for weeks.
It was months, it was painful to swallow, you know, bad stuff. Lots of people have had to have bad stuff
like this. And what I realized, you know, this is, it's a deeply unempowering situation to be a medical patient, particularly when there's something serious.
You have a limited sense of agency.
Things are being done to you.
Drugs go in you that make you feel really bad.
There isn't that much to do when I realized that for me the sense of agency came from being curious,
from being a total nerd about things. And part of what it made me curious about was my own mental processes as they related to my cancer and my cancer diagnosis.
So, for example, I'm getting in the chemo and I should just say as background, I'm fortunate.
I don't have a tendency for depression.
I'm a pretty upbeat guy.
I don't take any credit for that.
I think I was just born lucky and raised lucky, right?
But day after day of feeling bad in your body from chemo,
boy, it's hard to be positive.
It really is.
I could not overcome it.
My mood, God, really, really low.
And I could tell myself, this is going to be over.
It's not going to go on forever.
You won't feel this way forever.
And you would think that as a rational person,
I could talk myself out of that mood, but I couldn't.
You know, probably because my brain was a wash
and interleukin' six and I couldn't overcome it.
I felt really low, but at the same time,
I was sort of out of a remove being a nerd about going like,
huh, I bet these cytokines are messing me up right now. I bet that's what's going on. And that gave me
some sense of agency in a time where otherwise, I really wouldn't have it. Another thing
that really brought home to me is this issue that we were discussing earlier about how
malleable perception is and perception of time in particular.
If someone had said to me, when I was healthy before I was diagnosed, you're going to die
in five years.
I would have gone, oh no, no, no, no, no, no, I'm 59 years old.
I should get way more than five years.
I got a lot of things to do.
Professional things, personal things, family things, I got a lot of things to do.
No, that wouldn't be right, I'd be very upset.
But, you know, if you told me
after my diagnosis of six to 18 months,
oh, you get five years, I'd do it.
Five years.
Yeah, that's pretty good.
I can do a lot in five years.
I can finish up in the lab
and I can do some good work
and I can spend time with my family and travel and
save our lives pleasures and do all kinds of things five years great
And of course, it's the same five years, right? The only thing that's different is the is the context
But I think the thing that
really I
thing that really I realized the most is that I really couldn't and still can't engage with the idea of myself being gone.
So yeah, I can do practical things.
I can update my will.
I can write letters for my people in my lab.
So if I kick off,
you know, they've got that to take to their next job. You know, I can do all these nuts
and bolts things. But in terms of genuinely engaging with my own demise, I really find
that as much as I try, I really can't do that. And at first I thought, well, that's just your own lack of imagination, Lenton.
It's just because you're not very good at this.
But the more I thought about it, I thought, actually, no.
This is a human thing.
This is a fundamental human thing.
And one of the things, when I look back on the 40 plus years
I've been doing neuroscience, that's different,
is that when I was first trained,
the brain was really described as a reactive structure.
Something happens in the world.
You know, it comes to your sense organs, your eyes, your ears,
it goes into your brain, it triggers some things.
You think you make decisions,
and then you make an action that goes out to your muscles
or, or, or, and that's the loop. And that's what the brain does. And what we have known
in more recent years is that actually when the brain is waiting for something to happen,
it's not just idling and spacing out, that the brain is at every moment, subconsciously trying to predict the near future.
Predicting the near future is predicated on the idea
that there will be a near future.
That is to say that you won't be dead and gone, right?
That there'll be a future for you.
And so I think that my ability,
which I think is actually a human,
I mean, not my ability, my failure, which I think is actually a human failure to truly engage with my own demise,
is a feature. It is a side effect of the fact that the brain is always trying to predict the future. And so that was interesting to me,
just as a way that my illness was revealing something about the brain.
But it also made me think a lot about the world's religions.
Religion is everywhere in the world.
If you ask anthropologists,
is there any society that doesn't have religious ideas?
They'll say no.
They say they don't always have the word religion,
they might just say, well, yeah, in this place,
everybody knows that the world's on the back of a turtle,
and this happened.
There are these rules.
I may not call it religion,
but every place in the world has religion.
Not everyone is religious,
but it is across cultural universal.
And most religions, absolutely every single one,
but almost every single one has stories of afterlife
for reincarnation in which your consciousness indoors.
Well, why would that be?
And in many religions, they've got a deal, right?
Follow these rules in life,
and then you'll be rewarded in the afterlife.
And that's a very general idea or punished in the afterlife.
Right.
And, you know, in some religions, you meld with the divine, in other religions,
you're reincarnated, is this or that?
You haven't heard hell, right?
There's there's variants, but but they share that your consciousness
indoors. And so why is this so popular all over the world? Well, I would hypothesize that it is a
side effect of the fact that the brain can't help but always trying to predict the future. When we can't imagine the world without us in it,
then we are forced to concoct stories of the afterlife. Fascinating. And makes me want to ask
about this feature of time perception. My undergraduate, graduate, and post-doc advisors all sadly died earlier,
early, really, by pretty much any standard. And I was fortunate enough to be in communication with
the last two as they were going through that process. Both of them described a heightened sense of gratitude,
especially for things that previously they had not
paid attention to.
So we call this noticing the little things.
But that makes me conclude that something about
the knowledge of one's impending death, however far off
that might be, shifts our attention, at least temporarily, leads to this sense of slowing
down a bit because in order to shift our attention to, quote unquote, the little things,
were things that we previously overlooked. There's this sense of slowing down
and we know from basic videography, photography,
that slowing down means an increase in frame rate.
Right, that, you know, shooting at strobe frame rates,
it gives you the perception of strobe.
Shooting at very high frame rates allows you
to see things in very slow motion. You're noticing subtle variations that normally you overlook.
I'm not trying to be overly reductionist about this process of enhanced gratitude that you
describe and how it was alongside in 10-sanger, but have you noticed a shift in your perception of time because
you were given initially this X number of months, and then now with the, you're still here,
fortunately, and with this open-ended, well, it wasn't the prediction that was given
to you by your oncologist, but it's unclear how long you're going to be here, right?
Which is how most of us exist.
You have the sense that it's sooner rather than later, but you don't really know.
So I'm curious as to how the idea that, okay, you have 12 months more to live versus more
than 12 months, but not infinite.
But of course, I know that I have, hopefully, have more than 12 months, but not infinite. But of course, I know that I've, hopefully,
have more than 12 months, but it's not infinite.
So, you know, this idea of the finish line, the cliff,
leaving aside whatever might happen afterwards,
I don't know, haven't been there.
It changes what we notice by way of changing
our perception of time.
I mean, this is a profound tuning of our perception.
What are your thoughts on that?
And do you notice the each sip of coffee?
You probably don't notice each step across the kitchen floor in the morning.
You're probably paying attention to your lovely wife and kids and things that day,
but presumably
it's dynamic, but what is your perception of time like now with the understanding that yes,
you made it through the past the gate that was predicted, but what lies ahead is uncertain.
Yeah, so that's really interesting. And I would say, definitely, my perception of time is slower, and it seems like an age
since I was diagnosed.
But I think part of that is because it's been action-packed.
In other words, since I was diagnosed, so many emotionally salient things, non-trivial things have happened.
So many intense discussions with my wife and my friends and the people in my lab.
My wife and I've taken a lot more vacations than we normally do.
So we're running all over the world, and there's a certain sense of packing it in that
I think influences time perception, but I would say actually for me personally,
the gratitude isn't about the little things. The gratitude is about the very biggest
things. The gratitude is gratitude for being a sentient being and having that blessing. The gratitude is for being
able to have a life where I can follow my own ideas and creativity and my gratitude is for choke up.
The profound love that I've felt from my wife and my children, you know, it's not the little stuff.
It's the big stuff that I think about when I think about gratitude. It's not noticing the subti.
It's, it's the big issues. And, you know, for me, I,
you know, I don't, I want to delay my death as much as possible, of course. But, But when I think about it, the part that makes me upset is leaving people behind.
It's not for myself.
I've had a great life.
I've had a lot of it.
I'm 61.
I like to go longer, but that's a pretty good run. I've gotten to do lots of things
in those 61 years and have wonderful loving interconnected experiences. And so the negative
part is about what I leave behind.
Certainly, what you've left behind is enormous and has been the consequence of actions long
before your diagnosis, which I think is a clear lesson to everyone.
I can't speak for you, but don't wait for the diagnosis.
You've mentioned the sense of agency that you felt by being able to pay attention to and explore your experience of,
let's call it what it is, impending death.
And at the same time, as you mentioned, you've amplified and accelerated the number of things that you've put into the world recently, writing incredible
articles about your experience of life and death. And we will of course link to those so people can
read them. I've read them all and they are profound and they don't just feel important. They
clearly are important. So very few people have your insight into the nervous system at the
mechanistic level, but also at this more holistic level that you've clearly displayed to us here
and in your research and in your book writing and public speaking. You know, I think it's a
it's a risky thing to ask somebody for advice, but I can't help myself because I think it's a risky thing to ask somebody for advice,
but I can't help myself.
Because I think it's a real opportunity
if you had advice to give to any and all of us
based on the whole experience, all of it from go, as they say.
Right.
If you're willing and feel free to pass,
but if you're willing, what is your advice?
Well, I would say the advice that is really universal
is what everybody already knows and is a bit trite,
but I'll say it.
Anyway, and that is appreciate what you got while you got it.
And, you know, this isn't any big secret, and everyone knows it.
I would say, for a subset of people, the way of the nerd is very empowering.
I don't think that's the case for everyone. I think for a subset of
people who are deeply curious as their nature, turning that curiosity to your own medical situation can be empowering and useful. But I don't think that
should be broad advice. I think that's only for a fraction of people, it's probably the worst thing
they could do. And there's nothing wrong with that. Everybody's, everybody's different, right? Not everyone should have adopted the way of the nerd, but for a fraction of people, it's a really, really good thing to do.
This is normally the portion of a conversation with a guest where I list off the many, many things
they've done and how grateful I am, and all of that is absolutely true in the case of you being here today and
the work you've done.
But I think it's self-evident how much you've done just accomplished, but how much knowledge
you've put into the world, and not just scientific knowledge, but knowledge about the human
experience of others and of yourself. And so I just want to extend it a giant thank you
on behalf of listeners and viewers and myself.
Thank you for coming here today.
Thank you for doing what you do.
And so great to still have you here
and to have this conversation.
And I hope it goes longer and no matter when it ends, you've done an enormous service
to humanity.
Well, thank you.
That's very kind.
It's been a pure pleasure to have this discussion with you.
Thanks, David.
Thank you for joining me today for this discussion with Dr. David Linden.
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