Huberman Lab - Dr. Diego Bohórquez: The Science of Your Gut Sense & the Gut-Brain Axis
Episode Date: May 27, 2024In this episode, my guest is Dr. Diego Bohórquez, PhD, professor of medicine and neurobiology at Duke University and a pioneering researcher into how we use our ‘gut sense.’ He describes how your... gut communicates to your brain and the rest of your body through hormones and neural connections to shape your thoughts, emotions, and behaviors. He explains how your gut senses a range of features such as temperature, pH, the macro- and micronutrients in our foods, and much more and signals that information to the brain to affect our food preferences, aversions, and cravings. Dr. Bohórquez describes his early life in the Amazon jungle and how exposure to traditional agriculture inspired his unique expertise combining nutrition, gastrointestinal physiology, and neuroscience. We discuss how the gut and brain integrate sensory cues, leading to our intuitive “gut sense” about food, people, and situations. This episode provides a scientific perspective into your gut sense to help you make better food choices and, indeed, to support better decision-making in all of life. For show notes, including referenced articles and additional resources, please visit hubermanlab.com. Thank you to our sponsors AG1: https://drinkag1.com/huberman Joovv: https://joovv.com/huberman LMNT: https://drinklmnt.com/huberman Helix Sleep: https://helixsleep.com/huberman InsideTracker: https://insidetracker.com/huberman Timestamps 00:00:00 Dr. Diego Bohórquez 00:02:37 Sponsors: Joovv, LMNT & Helix Sleep; YouTube, Spotify & Apple Subscribe 00:06:49 Gut-Brain Axis 00:11:35 Gut Sensing, Hormones 00:15:26 Green Fluorescent Protein; Neuropod Cells & Environment Sensing 00:26:57 Brain & Gut Connection, Experimental Tools & Rabies Virus 00:35:28 Sponsor: AG1 00:37:00 Neuropod Cells & Nutrient Sensing 00:43:55 Gastric Bypass Surgery, Cravings & Food Choice 00:51:14 Optogenetics; Sugar Preference & Neuropod Cells 01:00:29 Gut-Brain Disorders, Irritable Bowel Syndrome 01:03:03 Sponsor: InsideTracker 01:04:04 Gut & Behavior; Gastric Bypass, Cravings & Alcohol 01:07:38 GLP-1, Ozempic, Neuropod Cells 01:11:46 Food Preference & Gut-Brain Axis, Protein 01:21:35 Protein & Sugar, Agriculture & ‘Three Sisters’ 01:25:16 Childhood, Military School; Academics, Nutrition & Nervous System 01:36:15 Plant Wisdom, Agriculture, Indigenous People 01:41:48 Evolution of Food Choices; Learning from Plants 01:48:15 Plant-Based Medicines; Amazonia, Guayusa Ritual & Chonta Palm 01:56:58 Yerba Mate, Chocolate, Guayusa 02:00:22 Brain, Gut & Sensory Integration; Variability 02:06:01 Electrical Patterns in Gut & Brain, “Hangry” 02:12:43 Gut Intuition, Food & Bonding; Subconscious & Superstition 02:22:00 Vagus Nerve & Learning, Humming 02:26:46 Digestive System & Memory; Body Sensing 02:32:51 Listening to the Body, Meditation 02:40:12 Zero-Cost Support, Spotify & Apple Reviews, YouTube Feedback, Sponsors, Social Media, Neural Network Newsletter Disclaimer
Transcript
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Welcome to the Huberman Lab Podcast, where we discuss science and science-based tools for everyday life.
I'm Andrew Huberman, and I'm a professor of neurobiology and ophthalmology at Stanford School of Medicine.
My guest today is Dr. Diego Borquez. Dr. Diego Borquez is a professor of medicine and neurobiology at Duke University.
He did his training in gastrointestinal physiology
and nutrition and later neuroscience.
And by combining that unique training and expertise,
he is considered a pioneer and leader
in so-called gut sensing or the gut brain axis.
Now, when most people hear the words gut brain axis,
they immediately think of the so-called microbiome,
which is extremely important,
but that is not the topic of Dr. Borges' expertise.
Dr. Borges focuses on the actual sensing
that occurs within one's gut,
just as one would sense light with their eyes
or sound waves with their ears for hearing.
Our gut contains receptors
that respond to specific components of food,
including amino acids, fats, sugars,
and other aspects of food, including temperature, acidity,
and other micronutrients that are contained in food that give our gut the clear picture of what
is happening at the level of the types and qualities of food that we ingest, and then
communicate that below our conscious detection to our brain in order to drive specific patterns of
thinking, emotion, and behavior. And of course, everybody has heard of our so-called
gut sense or our ability to believe or feel certain things
based on perceptions that are below or somehow different
from conventional language.
Today, Dr. Borges teaches us about all aspects
of gut sensing, how it occurs at the level
of specific neurons and neural circuits,
how the brain responds to that,
how specific foods and components of food impact,
not just our feeling of digestion or feeling good
or bad about what we ate, but indeed how we feel overall,
how safe we feel, how excited we feel,
whether or not we feel depressed or sad, angry or happy.
Today's discussion, I promise you, is unique
among all discussions of neuroscience,
at least that I've heard previously, in that it combines two seemingly disparate fields,
nutrition and neuroscience.
Indeed, today's discussion gets into how different foods and food combinations impact how we
feel and what we crave and what we tend to avoid.
We also get to hear the absolutely extraordinary story of Dr. Borke's upbringing in the Amazon
jungle and how his knowledge and intuition
about plants has influenced his science
and how the incredible science that his laboratory is doing
relates to all of us and our ability to better tap
into our gut sense.
Before we begin, I'd like to emphasize that this podcast
is separate from my teaching and research roles at Stanford.
It is however, part of my desire and effort
to bring zero cost to consumer information
about science and science related tools
to the general public.
In keeping with that theme,
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And now for my discussion with Dr. Diego Borges.
Dr. Diego Borges, great to have you here.
Thank you for having me, Andrew.
I am super excited to learn from you today,
as I know everyone else is.
And if they don't realize why, soon they will,
which is that you work on one
of the more fascinating aspects of us,
which is our gut, our gut sensing, the gut brain axis,
which I think most people don't realize is nearby,
but separate from the so-called microbiome.
So we're not talking about the microbiome,
a very interesting and important topic, of course,
but we are going to talk about this thing
that we call our gut sense
and how it impacts everything from our cravings
to our brain health and our cognition.
So once again, welcome.
And I'll just wanna kick things off
by asking you to educate us, explain, you know,
what is this gut brain axis that we hear about
and what's going on in our gut besides digestion?
Well, Andrew, thank you so much for having me here.
I'm thrilled to be here. I knew that since we met a few years ago that we will have
this ongoing conversation and a great conversation. The gut and the brain, you know, people call it
an axis because traditionally thought to be an imaginary line that was connected through hormones.
So since 1902 when the first hormone secretion was reported
by Bailey's and Sterling, it was known that when we eat,
then hormones,
these molecules in the gut are released
and then they will enter the bloodstream
and then eventually will have a cause in distant organs.
And for the next hundred or so years,
the field focus on the hormones.
And as a consequence, there was no direct line
of communication between the gut and
the brain.
But as often I say, you don't say or we don't say the nose brain axis, right, or the eye
brain axis, right?
And all of the organs are in sync, working in sync. So, in the gut, there are also some sensory cells that are able to detect the outside world
and then quickly communicate that information to the brain.
And I say the outside world because the gut is the only organ that passes throughout our body,
but it is still exposed to the outside. If you think about it, if you will swallow a marble,
it still has a chance to get out.
Please don't do that, anybody.
But it's still exposed to the surface.
You're right, I never thought about the gut
as the organ that is in contact with the outside world,
unlike our heart, which is not in direct contact
with the outside world, or our liver, which is not in direct contact with the outside world, or our liver, or our pancreas,
but the gut is.
The gut is, and if you think about it,
it's just separated by some compartments
that have all of these valves,
and the epiglottis, the gastroesophageal junction,
the pylorus, the ileocecal junction, the rectum.
So these are the sequences of valves, of chambers with valves between them, that food passes
through, air passes through, and within each, as I understand it, there are different functions
related to digestion.
But I think where you're taking us is that there are
different modes of sensing what's coming through
and signaling to the brain and other organs
what's going on in the outside world
by what's sensed coming through that passage.
Is that correct?
That's correct.
And if we think about it,
when we swallow something,
literally we have to trust our gut.
Perhaps that's why we use this phrase, trust your gut, right?
Because after that, there's not much that you can do, at least in regular humans, that
you can do consciously to expel something that perhaps is poisonous or toxic, right?
It is the gut that has to make the distinction and then usually accommodate things for absorption
or let them pass through digestion and then ultimately they will be secreted, right?
So if you could describe for us the architecture that is the cells that respond to things in
the gut
and where they send that information
and how they send that information.
What is this thing that we call gut sensing made up of?
What's the parts list?
So the parts list has been evolving recently
and while some of the elements we have known for a while,
but in general what we're talking about,
because it's an external surface,
it is lined by a single layer of cells
that are called epithelial cells.
And essentially these cells are exposed
to the outside world,
but they also are like attached in like a little membrane.
And they are the ones that interface
with the inside of the body.
So in the stomach, we have an stratified epithelium,
for instance, that is thicker,
so it can survive digestion chemicals
and other things like harsh environment.
And in the intestine, we have a little bit more of a
more delicate epithelial layer.
And within this epithelial layer,
there are several different cell types.
And one of those is the so-called enteroendocrine cell.
To put it in more simple terms,
is a gut endocrine cell or a gut cell that releases hormones.
The term was coined in 1938 by a German physician.
His name was Frederick Fetter.
And at that time, it was a major advancement
in our understanding of physiology
because he came up with the idea that the organs were not
only communicating to organs.
In fact, there were cells within the organs
that were communicating to other organs
through the release of some
of these endocrine factors, these neuromodulators or these neuropeptides that we know as hormones.
And so he named the diffuse endocrine system of the gut and then he came up with this word
enteroendocrine cell.
And these cells are these pairs at a ratio of roughly speaking like 1 to 1,000 epithelial cells throughout
the digestive tract.
And we thought for the longest time that these cells were not connecting directly to the
nervous system, that they will release these neuromodulators and the neuromodulators through
diffusion will act on receptors into some of the nerve terminals.
And that is true.
That is a very well-established system.
But in 2015, we made an observation
that some of these cells,
anywhere from one-third to two-thirds of these cells,
it depends on the type of systems
that you use to identify it,
they were contacting directly the nervous system.
And that brought up a new dimension
of how it is that the gut could be communicating
to the brain because as you know in the brain the synapses are the ones that are most predominant.
However, there is a lot of neuromodulation from endocrine functions in the brain too.
So in the gut, this was not well described.
There had been historically a few examples
that these cells may be making synaptic contacts,
but they had not been studied.
And perhaps one of the main reasons why they had them being
studied is because the tools were not there.
And if you recall in the 1990s with the advancement
of green fluorescence protein as one of the main molecules to tag
cells, now all of a sudden there was a revolution in biology because you could identify the
cells, you can take them out, you can do a transcriptomic analysis to see what genes
they express.
You could co-culture them, you can modify their genome, and then you can start to interrogate
what is their contribution to the entire body.
I'll just interrupt you for a second just to make sure that I and everyone else is on
board.
So if I understand correctly, it's long been known that there are cells that are in these
layers of the gut in the intestine, and it's long been appreciated that as food passes
through, these cells somehow can sense
the chemical constituents of the food as it gets broken down and then release hormones
into the bloodstream that could influence the brain.
Those hormones could travel and influence things far away.
In fact, for those that don't know, endocrine generally means signaling at a distance between
cells.
So between gut and brain or gut and liver. It can also mean local effects.
Hormones and endocrine effects can also be local.
But if I also understand you correctly, it was only about 15 years ago when you mentioned
green fluorescent protein.
We should probably just tell the tale in a few sentences.
This is an amazing story in biology where if you've ever seen fluorescing jellyfish,
that's because they express a gene for so-called green fluorescent protein, and biologists
have hijacked that gene sequence and put it into mice and now actually other organisms
as well, which allows you to see individual cells and cell types.
So these cells release hormones.
The hormones influence the brain and other organs.
And now I think you're gonna tell us
that they also are able to make
direct communication lines with other organs as well.
Correct.
So maybe here is fitting how it is
that I got into starting the system.
And as you know, between the 90s and the early 2000s, there was an explosion in tools to
study the brain and neural circuitry and the connection of neurons and each one of the
neurons.
Because up until the 1990s, the tools were limited, electrophysiology, you know, behavior.
But then not only we had a green fluorescence protein, we had optogenetics.
We had rabies modified to be able to trace how it is that neurons connect at one synapse,
which was a dream.
I think that in fact that was the dream of Francis Crick when he was at the Salk.
He talked about having a way to control.
For those that don't know, Crick won, was a co-recipient to the Nobel Prize for the
discovery of the structured DNA, but then later in his career, developed an obsession
for neuroscience.
Yeah, he daydreamed out loud about having tools to visualize individual connections
in the nervous system. And as Diego is pointing out,
scientists have hijacked the rabies virus,
which hops between neurons,
labeled the rabies virus with things that glow fluorescent.
And in doing so, we now understand a lot
about what Crick dreamed for,
which was the ability to see different specific connections
in the nervous system.
Yes.
So then you could isolate the cells and then you could do sequencing technology to see
like what are the genes that these cells are expressing and then you can start to understand
the makeup of the cells.
In 2009, Hans Kleber is a scientist in the Netherlands.
He did a beautiful experiment.
He discovered these factors that will trigger a receptor of the stem cells in the intestinal
epithelium and will form literally a mini gut in a dish.
These cells will be all lined up and then they will have a lumen.
And I remember seeing some of these papers coming out when I was a PhD student and I
was already studying the gut.
So it was inspiring to see like all of the things that all of a sudden you could do,
right?
So when I began studying the cells, immediately by isolating the cells and simply observing
the cells in the native tissue of these mice models,
it quickly became evident that some of the cells
had a very peculiar anatomy.
Some of them had these very prominent arms at the base,
like literally like in the Sistine Chapel,
Adam reaching out to God, right, like with the hunt.
The cells will have that type of anatomical features, and even ending with a little hand
at the end of that arm.
And obviously, I immediately thought, like, why would a cell that it is supposed to react
to food and release hormones into the bloodstream or just in the vicinity will invest
so much energy into developing an arm, right?
So then I started to look, well, perhaps it is because it's providing a breach directly
into the vasculature, into the vessels to put the hormones into the bloodstream, right?
Grown.
You know, like I couldn't find that direct connection.
So then I started to study perhaps they were associated
with the nervous system, and that's how we made some of the
first observations that some of them, with the arm or without
the arm, they will have a more intimate relationship with
nerve fibers. And that, of course, opened up a bunch of new questions.
But the first thing that we had to do, it was to come up with a name for this foot.
And it kind of became organic.
And I want to highlight this because I think that as we go through the discovery trajectory, we don't realize the need to also
engineer language.
How we go about language is we start to attach words that we already knew and we start to
put them together to describe something that knew that we're observing, right?
And I say this because at the very beginning with my mentor, we will start to call these
little feet.
First, we call them axon, which is like the term
for like the long extending branches of the neurons,
the main branches of the neurons.
So we will call them axon-like
because they look like a baby axon.
But then we call them also like pseudopod
because it was like a pod, but it was pseudo.
And at some point we, and it was coming from like some cells in the kidneys that they are called podia
or something like that.
So it was axon-like, pseudopod-like, basal process
to describe that it was on the base.
So at some point it became so long
that we couldn't fit it in an abstract, right?
So then-
Yeah, it's a bit of a mouthful.
So we began thinking about it,
and then eventually I came up with a term I thought like,
ah, neuropod.
And I remember pitching it to my mentor,
and he said, like, let me think about the weekend.
And then on a Monday, he came in, and he said, like,
you know, it has a ring to it.
I think that we should use it.
But essentially, the thought was that
if these cells are contacting, then perhaps they are
passing information directly onto the nervous system.
And that is very different than just spewing neuromodulators in the vicinity and hoping
that some of those catch the nervous system, right?
And like I said, while that still exists, and I think that is just like matter of space
and time.
Like, they modulate these terminals in a different space and time, the hormones.
But the transmission, the neurotransmission is directly and more precise in space and
time.
Could I just interrupt for a moment, please? Hormone signaling, endocrine signaling, generally is slower than the forms of communication
directly between neurons, right?
Could be on the order of seconds, sure, but typically on the orders of minutes or hours,
whereas neural communication on the order of milliseconds.
Correct. So, if I understand correctly, these, what you decide to call neuropod cells, and thank
you for shortening the name from the other description, line the gut.
Are we talking about everything from esophagus down to the stomach to the intestine, or is
it just at the level of the stomach and intestine?
Where does it exist?
This is where the conversation becomes expansive because these neuro pods or cautions of these
neuro pods, so these neuro pods are simply specialized neuro epithelial cells, meaning
that are electrically excitable, that they can discharge electricity. But they are, these type of cells are in every single epithelial cell or epithelial layer
of the body, because that's how the body creates a representation of the world through sensor
cells that are equipped to detect the outside world, meaning that they can be exposed to
fluctuations in temperature, fluctuations in pH, fluctuations in concentrations.
And then they quickly can generate a chemoelectrical code that they pass it on to the nervous system
and then ultimately the brain integrates that and says like, oh, my belly is feeling good,
but I'm feeling cold in the skin, right?
And that is thanks to all of these neuropithelial cells
that they are even in tasting, so to speak.
They are the cerebrospinal fluid
inside of the spinal cord and the ventricles.
They are inside of the inner ears, the taste, the taste buds.
So it is, and in fact, there's a beautiful book from the 70s
from some Japanese scientists, Fujita Kanon Kobayashi
who called the cells para neurons.
And their whole concept is that there was not
such a discrete distinction between an entire neuron
that lives inside of the brain or the central nervous system
and a neuro epithelial or a neuro endocrine cell
that leaves exposed to the outside, simply
that there is a continuum of adaptation so the organism can bring the information from
outside inside into the body to be able to process it and then process it and then guide
behavior.
So, based on the way you describe it, we have these neuropod cells that line our gut, and
we also have these similar cell types in the other organs of the body, and these cells
are responding to the chemical constituents of what we eat as the food is broken down,
also to the temperature of the environment, to the pH, that is how relatively basic or acidic something is that we ate,
and presumably to other features in our environment as well.
And all of that information is activating these cells to some degree or another,
and then we're releasing hormones into our body as a consequence,
but also there's a direct line to the brain.
And we're not necessarily aware of all of this happening.
I mean, until you describe it, I think most of us
have not been aware that this is happening.
And we probably shouldn't be aware.
Like as I often say, like if you and I are having a conversation,
we probably shouldn't be aware of the macrophage in the spleen
that is chasing this bacterium that it got inside of the lettuce that we swallowed at lunch,
right?
Like, just do your thing so we can keep communicating, right?
Except maybe don't eat more of that lettuce, right?
Which is the...
That's right.
Okay.
So you discovered these neuropod cells.
That's right.
Or I described them.
You described them, yeah.
And you had in hand some tools to selectively label them.
What did that reveal about their connectivity with, you're referring to it as the nervous
system, which I love because a resounding theme on this podcast is I always say, you
know, brain and spinal cord and all the connections to the body and back again is the nervous
system.
But what did you discover in terms of the connections with the brain proper?
Here is where the tools started to make a big difference.
All of a sudden you could see the resolution of a receptor inside of a cell using certain
type of microscopes.
I remember that one of the first questions that I will always get drill on, you know
how these laugh
meetings can get intense, right? Like when I will bring data and showing just very
simple immunohistochemistry, meaning labeling to see how the cells were
interacting with the nervous system. As I will show some of the images, then the
other scientists will say, well you know yeah, those are nice images, but
remember that contact does not mean connection.
And then I went thinking about that.
Like at the very beginning, I thought that it was silly semantics, you know.
But I specifically remember that there was one time I was running and I was thinking,
like, how do you demonstrate connection between two cells?
And then I thought that since we had the ability to identify
these cells by fluorescence, we could isolate them
based on their fluorescence.
And what will happen if we put them
in front of a sensory neuron and then just record them
inside of a microscope over time?
And I thought maybe they will get close to each other,
and then we can go and do some more labeling and show that they are contacting or connecting.
But much to our surprise, we actually saw that in real time, when you isolate them from the mouse and you put them in a dish, they both look like these round circles.
But after a few hours, not only they get close to each other, but they recapitulate the circuitry
in the dish.
Literally, they form like two brains in a dish, right?
Like it's the gut and the brain in a dish.
Yeah, and that was an eye-opener.
I still remember it was somewhere, I think it was like June 27, 2012 when I saw that
experiment because it opened my eyes to so many different things.
One was that these cells are not static because since we have been seeing them for decades
judging as slices or fixed tissue, we have lost the notion that this thing is constantly
moving, right?
The cells are actually moving.
The cells are actually moving.
So these cells line the gut, meaning they're along the walls of the gut, the intestine.
They reach a hand into the gut to sense whatever chemicals are there.
Yeah, they have little cilia, little hair or microbe lie that is literally like little
hair that is exposed to the lumen.
So the lumen, folks, is the cavity, the empty cavity of the gut.
Not empty, but the internal part.
And so they're sensing the chemicals there, and you're saying they can move, okay?
And they're sending a process.
By the way, folks, anytime you don't know whether or not something is a dendrite or
an axon, just call it a process.
You'll get it right.
A process up to the brain.
Underneath, that will connect to the nervous system.
I see.
So through a series of stations.
Yeah.
Okay.
Amazing.
So, what we're talking about here is Diego's discovery of a pathway from the gut to the
brain that essentially allows sensing of what's happening in the gut to inform feelings,
decisions.
That's correct.
Yeah.
So that was the first experiment, like showing in a dish, right?
The next experiment was, well, does it happen in the mouse?
And then through a series of, I have a friend, neuroscientist, that she calls these rabies
gymnastics because you have to put in some genes and make things work.
Then we demonstrated that these cells,
that the virus will be capable of infecting these cells
specifically instead of infecting the other reptile cells,
it will infect these neuro-reptile cells
because rabies likes neurons.
And then it will jump from that cell into a nerve fiber.
And these rabies can only jump one connection, right?
And what was surprising is that the fluorescence from the rabies will show up in the brain stem
and in the bodies of the cells that are in the nodos ganglia, which is this cluster
where the cell bodies of the neurons
of the vagus nerve are located right underneath the neck.
Meaning that there was just one stop between the surface
of the intestine and the brain stem.
The two cells were connecting that space, you know.
So obviously the information, that was the anatomical basis
for the information to travel very rapidly
up into the brain.
And rapidly in the subconscious, right?
Like we're not necessarily aware of it,
although I've read that there are some instances
in which people become more aware of it,
either in a atypical fashion or with meditation
and other things that people can become aware.
Yes, people definitely can become more aware
of their so-called interoception,
what's going on at the level of their heartbeat frequency
or their gut sensing if they spend time on it.
Some people, as you mentioned, develop an almost pathologic sense of interoception such
that they have trouble navigating normal life because they're so aware of what's going on
inside their body.
This is actually an interesting issue in the field of psychiatry.
My colleagues in psychiatry at Stanford tell me that some people with a lot of anxiety,
for instance, are so aware of their heartbeat
that it becomes disruptive and distracting to them.
So it's not always the case
that it's better to become more aware
of your internal processing.
Sometimes it can be deleterious.
Other times it can be good for us.
Some people are very unaware
of what's happening in their body
and they need to develop more awareness of that.
I feel like as long as we're talking about rabies, we should have a little bit of fun
and explain to people something about rabies viruses because what we've been talking about
is the use of viruses as experimental tools in order to take a virus, basically attach
or put something in so that whatever cell is infected by it glows a certain
color so you can see the cells and visualize the circuitry.
But as long as we're talking about rabies, I feel like it's such a word that has such
salience.
The rabies virus, which exists in nature, is amazing because it's... I don't know if
it has a consciousness, but it essentially propagates between animals by way of the animals that have it bite.
They become more aggressive.
They bite a target animal.
The virus gets in, it's picked up by the nerve terminals and is carried back from one cell
to the next across synaptic connections, right?
Synapses that get little gaps between neurons. And what Dr. Diego Borges has been telling us is that scientists have engineered the
rabies virus so that it only jumps one station and then stops.
You can do this by modifying the coat protein.
There's a bunch of fun virology that can be done to do that.
But what I find amazing about rabies virus, and there's a great book, by the way, called Rabid,
which is essentially a history of the study of rabies,
is that once it travels from the site of the bite
up to the brain, what does it do?
It changes the brain to make the now infected animal
or person more aggressive so that then they
go bite somebody else.
So, I mean, in some ways that the viruses have a sort of unconscious genius to them, right? What's the best way to get from one animal to the next? Well, there are a number of different ways,
but one way is to just make that animal more aggressive so it goes and bites things.
Yeah, make that animal work for you.
Make the animal work for you, right? It's almost exploitive, right?
It exploits a certain circuitry in the nervous system.
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Okay, so you identified these, you said described,
but I'll say discovered, because that's what happened.
You discovered these cells, you label their connections,
you see that there's just two stations between these cells,
or one station really between these cells and the brain.
And so now these cells can sense chemicals in the gut
that are the consequence of the breakdown of food
and send that information directly to the brain of the breakdown of food and send that information
directly to the brain.
What does the brain do with that information?
All right.
So here comes the key experiment.
And this was building obviously on the work of other scientists that had already described
that the gut had some receptors for sugars, specifically for glucose, for other nutrients.
Around this area in the early 2000s, when we were starting to be able to identify some
of these cells, then it quickly became obvious that these cells, these enteroendocrine cells,
throughout the lining of the stomach, intestine, colon, they had multiple receptors for multiple nutrients.
You know, like we have the macronutrients, for instance, sugars, fats, proteins, but
within them we have, you know, a repertoire of molecules, you know, multiple lipids, multiple
types of sugars and so on and so forth.
And these cells, depending on their location, they will express a different type of receptors
or a combination
of those receptors.
And I said depending on the location because when we're eating, let's say an apple, you
know, the apple is going to be partially undigested by the time that it enters the intestine,
but by the time that it gets to the colon, most of those nutrients have been absorbed
and perhaps only fibers are surviving to feed off most of the microbes that live in the
colon, right?
So the gut has evolved to mirror and to become a Velcro to the molecules that will be in
that specific space, so it will detect.
So it will detect sugars more in the proximal intestine, but fibers are fermented by products more
in the distal intestine or in the colon, like short-chain fatty acids, butyrate, propionate,
and so on and so forth.
You know?
What other kinds of nutrients do these neuropod cells detect from food?
You mentioned sugars.
You mentioned fermentation, presumably short and long chain fatty acids?
Yes, the short answer is that I think that in due time,
we are gonna realize that they detect just about
every single thing that we put on our mouths every day.
That they have some either an specific receptor
that is dedicated to it or a combination of receptors
to be able to detect some of these
compounds.
And not only the chemical compounds, but also an area that I think that is going to be fascinating
in the future is the mechanical extension plus the adjustment in temperature as the
chyme starts to flow from the mouth into the colon. Like for instance, I heard this from a bioengineer not long ago
that was engineering artificial gut and stomach.
And he shared with me a piece of information that I was not aware of
that the sophagus has to adjust the temperature of the food very rapidly
within seconds into physiological temperature of the inside of the food very rapidly within seconds into physiological temperature of
the inside of the body.
So we're having hot coffee within a couple of seconds.
It has to be at the physiological temperature of the body by the time that it gets into
the stomach.
Right?
And all of that happens in very rapidly.
Amazing.
In the sufferers, right?
So if I understand correctly, these neuropod cells have a variety of different receptors depending on where they are located along the trajectory from the mouth to the rectum.
That's correct.
Some are sensing sugar, some are sensing temperature, some are sensing pH, so relative acidity.
Some are sensing amino acids, presumably. I mean, I've heard it said, and I believe there's a researcher down in Australia who's been very bullish on the theory that we are not exclusively, but we are predominantly amino acid foraging machines because we need amino acids for all sorts of important biological processes. And these cells are essentially evaluating how much sugar, how much leucine, how much
short chain fatty acid, how much essential fatty acids of different kinds, and then making
changes to the gut itself, but then presumably signaling that information elsewhere in the
body.
So here I'm going to give you something that will get your gut churning, so to speak.
So these cells have to make sense not only of the molecule that had been adjusted, meaning
the chemistry of the molecule.
Let's say if it's glucose, it has to make sense a little bit of the taste.
Is it sweet?
Right?
Is it bitter?
Then it has to take into account how much of the molecule
is absorbed inside of the cell, right? So that's the second layer of integration. Then
once the cell has eaten that molecule, so to speak, then that molecule will be digested
inside of the cell to release ATP or some other compound. ATP is for energy, for instance.
That has also have to be taken into account.
For instance, in glucose.
Glucose activates the TAS1R3, which is a sweet taste receptor.
Then the glucose is absorbed by some of the sodium glucose
transporters, which are active transporters.
And these transporters depolarize the cell.
And then once glucose gets inside of the cell, glucose enters the TCA cycle,
is catabolized, and then produces ATP.
And the ATP further activates another voltage-gated channel,
further depolarizing the cell.
And then the cell releases, in turn, a transmitter, for instance, glutamate,
that very rapidly tells
the vagus nerve within milliseconds, you know, I got sugar.
And it tells it in two phases because that glutamate will activate two different type
of receptors, ionotropic, which are very fast, and metabotropic, which are a little bit more
delayed.
But then the metabolism of that glucose that produces the ATP and further depolarizes the
cell, we believe that it will cause the release of the hormone, of the neuropeptide.
So then the neuropeptide comes on top of that and gives you that full experience of what
it means to consume sugar, right?
So that happens at the level of one cell
and at the level of one molecule.
So imagine like all of the computation that the gut has to be making for each one of the molecules throughout the digestive tract.
So if I stand back from this picture
what I get is
there are very interesting cell types that line our gut that are evaluating all of the, not just macronutrients,
proteins, fats, and carbohydrates,
but micronutrients within the food we eat,
as well as some of the other qualitative features,
temperature, for instance, maybe even quality
of the amino acids or the sugars,
you know, simple versus complex sugars, et cetera.
If we could just further zoom out for a moment
and take a human perspective on this
at the level of experience.
I once heard you tell a story about someone you knew
who changed their gut radically,
and that changed their entire perceptual experience of food, including certain cravings.
Would you mind sharing that story?
Yes.
Thank you for bringing that story, Andrew.
That story is very personal to me.
I often say when I get on stage that we are constantly influenced by two things in life,
the food that we eat and the people that we meet. Now, we have known each other, but now we meet in person and we are knowing other people.
I remember that when I was starting my PhD in nutrition at North Carolina State University,
so I didn't grow up in the United States, I grew up in Ecuador.
I was invited to my first Thanksgiving celebration.
So I sat at dinner and, you know,
as we began chatting with the people
that were next to each other,
all of a sudden I was enthralled in this conversation
of a woman telling me this story about her experience
with gastric bypass surgery for treating obesity.
So gastric bypass surgery was began to be developed by surgeons in the 60s.
And by the 90s, it had become a mainstream type of surgery for
the treatment of chronic obesity.
So she told me that there were primarily three things that happened.
She said, well,
within six months of the surgery, I had lost about 40% of body weight. She said, like I
was about 300 pounds, you do the math. So it was a significant amount. She said, within
one week of the surgery, my diabetes was gone. she said. I did not need more insulin shots.
So I had the same reaction that you're having.
I was like, I don't know much about diabetes,
but I know that it's a major health burden, right?
But the thing that really caught my eye was when she said,
but since you're studying nutrition,
I want you to answer this to me.
She said, why is it that before the surgery,
I could not even look at sunny side up eggs?
She said, just looking at the yolk will make me queasy.
But after the surgery, not only I can eat sunny side up eggs,
I actually have a craving for the yolk.
She said, every time we go on Saturday
to a restaurant for breakfast, I will take the toast and I will actually clean the plate of the yolk, she said. Every time we go on Saturday to a restaurant for breakfast, I will take the toast and I
will actually clean the plate of the yolk.
So how is either rewiring the gut alter my perception of flavor, alter my cravings and
my mind to get the yolk, she said.
And even inverted her sense of what was aversive versus a repetitive.
And I guess for those of us that don't know,
meaning me, I understand that gastric bypass surgery involves the removal of a portion
of the gut. How much gut tissue do they actually take? Is it centimeters, inches? The gut's
a long distance. So what do they do for gastric bypass? So in simple terms, the most,
the classic surgery is called
Roux-en-Y gastric bypass surgery,
which involves a reduction of the stomach
and short cutting the connection of the stomach
to the intestine.
So you will cut, you know, one third,
which will be the duodenum.
One third of that will be cut,
and then that portion will be reconnected to the stomach,
meaning that you're short-circuiting the gut.
And the whole idea was, at the very beginning,
was like, well, if we reduce the surface
that is exposed to food,
then we can reduce body weight by the
simply reduction of surface that is exposed to the food that is absorbed, right?
And what it became very clear is that well before the body weight changes got taken place,
there was already like some dramatic changes in physiology like the hormones, the neuropeptides
that were released from the intestine in response to nutrients, you know, will change very rapidly.
Then as I mentioned, the food choices will change, diabetes will be resolved.
So then it became obvious that it was not necessarily just the reduction in the surface
of the gut.
So that's one of the main surgeries.
The other one, as I understand, is vertical sleeve gastrectomy.
And this vertical sleeve gastrectomy is simply a reduction in the size of the stomach.
So now the stomach is very tiny and the idea is that it will accumulate less, it could
hold less food and then the food will go very tiny and the idea is that it could hold less food and then
the food will go very rapidly into the intestine.
And what is becoming very obvious is that there is a rapid change in the sensory function
of the gastrointestinal tract.
So the gut seems to rapidly shift, perhaps become more, so to speak, in general terms,
more sensitive to the presence of nutrients,
right?
Interesting.
So this woman that you met at Thanksgiving had gastric bypass surgery, and presumably,
I think it's fair to assume, a good number of these neuropod cells that sense different
nutrients were removed.
And as a consequence, she completely shifted her craving of a particular food.
And is there any sense whether or not, no pun intended, the lack of sensing of what
was in, you know, Sunnyside egg yolks was somehow related to a shift in appetite or
something else?
Or is it merely a qualitative, albeit a dramatic qualitative shift in what she craved?
So two contextual pieces of information. So I remember leaving the dinner and I was like,
whoa, this is major, you know, like I'm sure that people have written about these or done research.
And I realized that it was very little was known.
Even gastroenterologists knew very little about this.
The first clinical report that the alteration in food choices
was common in these patients came out, I believe, in 2011.
And then later on, scientists replicated that even in rats
or in mice.
We have done it in the laboratory.
And consistently, they change their food preferences,
their food choices.
So in recent years, we have been starting that system.
And I will tell you that in 2022,
this is another important contextual piece
that we have not gotten to it.
So after we found and we described
that the cells were connecting to the nervous system
and that they were sending information
up to the brain very rapidly,
the challenge was, well, if this is a sense, what behavior is affecting, right?
Like how is it that is affecting the responses of the organism?
And that took a little bit of a technical hurdle.
And here is where optogenetics comes in.
Yeah.
Please explain for people what optogenetics is, at least at a top contour level.
Yeah. at least at a top contour level. Yeah, so optogenetics in 2005,
Professor Carl Dysero, Ed Boyden,
and other scientists had been able to make this dream
of an experiment, which was isolate the genes
that encode for these opscenes that are sensitive
to specific wavelengths of light and put them into neurons.
And now by turning that light, they could make the neuron activate.
And then ultimately, then later on, they went on to describe that that could be used to
control specific cells that are regulating behavior.
And then by that define what cells are orchestrating certain type of behaviors like movement,
foot intake, thirst, anxiety, so on and so forth.
So in 2014 we began trying to adapt that technology to the gut.
Very quickly we realized that the way that light was brought into the brain
was through a fiber optic cable that was rigid.
And in the brain, you know, it helps that it's actually rigid.
But in the gut, it doesn't help because the gut is constantly moving and so on and so
forth.
So it's not compatible for running those experiments.
And here's where I usually say, like, you know, we really don't know what is going on
because some forces like move around us. And in 2017, Professor Polina Nikieva from MIT came to give a talk at Duke, and she reached
out to me.
And literally she came and as we were chatting, she said, like, Diego, I see that you're working
between in this interface of the gut and the brain, and I have this fiber optic that is
flexible, you know, will you have
any use for it?
So with that fiber optic, that made a big difference to study interrogate the function
of these cells to behavior.
So when we were able to put those options, the light-sensitive proteins inside of these neuro pods. Now when we turn the light on to shut off these cells very rapidly,
we found something very interesting. So normally animals, when you give them the
choice between a sweetener, which is devoid of caloric value. So like a aspartame or stevia or something. Yeah. Yep.
And you give them sugar, table sugar, the animal invariably will go to sugar.
They prefer sugar.
They prefer sugar.
You know, if they have never seen sugar, it will take them a little bit more time.
But regularly, by the second day is within 90 seconds that they detect what is sugar.
So they're drinking out of one tube,
they get some water with stevia,
they drink out of another tube water with sugar,
and they invariably prefer the water with sugar.
That's correct.
And people have described this phenomenon for a while,
and in fact, in 2007, there was an elegant experiment
done by Professor Ivan de Araujo at Duke University,
in which the sweet taste receptors were,
or the taste receptors were genetically erased.
And the animals were not capable of distinguishing
the sugar, the sweetener from the water, but
they could still distinguish sugar from water, meaning that there was something else that
was detecting that sugar.
So just to make sure people are on board, an experiment where sensing of sweet taste
at the level of the mouth is eliminated,
does not disrupt the preference for sugar water.
Correct.
Which means that there's something going on
below the depth of consciousness that causes mammals,
presumably us included, to prefer things that have sugar.
Yes, and then Professor Tony Esclafani, he
had been studying these behaviors.
And he went in so far to suggest that perhaps these sodium
glucose transporters are some of the ones that
are detecting the sugar as it enters the intestine.
And that's what is causing the behavior.
So we began working on the system.
And we wondered, could these cells be the ones that are guiding
that behavior?
And around the time that we published this work, Professor Charles Zucker at Columbia
also further advanced that area by building on the previous work and demonstrated that
there were a population of neurons in the brainstem that were
integrating this information from the gut.
And by that, the gut and the brain were guiding
these behaviors, so.
And it is true that from the earliest of ages,
we crave sugar, or at least if we are exposed
to the taste of sugar,
it tends to drive seeking of more sugar.
I mean, you can see that in babies even.
Correct.
And as I usually say, I call it instinctively
because our mother doesn't have to teach us,
hey Diego, that is glucose, you know.
It may present us in some ways,
but at the end of the day, I have to go
and get my glucose,
get my amino acids right.
Because eating is very simple.
We're just trying to solve this issue of getting our carbons, getting our nitrogen, getting
our phosphorus, our potassium, our sodium, and our chloride in so many different ways,
shapes, or forms, right?
So I went back to the experiment, the key experiment.
So when we were able to put these opsins and bring the light and shut off these cells very
rapidly when we had presented the animal with a choice of sweetener over sugar, then all
of a sudden the animal became blind to the solutions.
It couldn't discern between the stevia, so to speak, or the sweetener
from the actual sugar.
And the entire manipulation, the experimental manipulation that is, is occurring at the
level of the gut.
The intestine, that's right.
Right after the stomach, it's like just a small portion of the intestine.
So if we make an attempt to transfer this to the human real world experience, if I have
some ice cream, it tastes sweet.
I like it.
I know I'm thinking about it and I'm craving it just a little bit.
I don't have a huge craving for sweets, but I do like some of them.
So eating ice cream, it tastes sweet.
The tendency is to crave more.
That's correct.
Right.
You have to eat a lot of ice cream before you're truly full.
And most people self-regulate or their parents regulate for them by limiting the number of
scoops or something.
And that sweet taste is part of the motivator. But what you're saying is that as the ice cream enters
the gut, there are neuropod cells there
that are also sensing the sugar and signaling to the brain.
And the brain is responding to pursue more
of that sweet containing substance.
That's correct.
And it's happening below our awareness.
It is independent from the sweet taste of the ice cream.
Correct.
The conscious sweet taste.
The conscious sweet taste.
Which if you think about it, it's not fully conscious, right?
You know, as a, what we detect of the world
is just a very tiny little portion, right?
Even sight, you know, like we think we are looking for light,
but I don't know what is happening behind my back.
I trust that everything is going okay, right?
So when we shut off the cells, the animal,
and as I usually say, like became blind to the sugars,
because it's kind of like a king to having turn off
the cells that are able to detect light, the wavelength of light, for us to be able to
discern color, right?
And it's not that the animal is losing its memory because then you remove the light and
now the cells are functional again, then the animal again is able to distinguish one solution over the other.
And then we did a couple more experiments in there.
And what happens if we do the reverse?
If we turn on the cells now?
And the fascinating thing is that when we turn on the cells, now the mouse will eat
the sweetener as if it will be sugar.
Interesting.
So the activation of these cells makes them crave non-caloric sweetener or low-calorie
sweetener as if it were sugar.
But is it blinding them to the difference between sugar and low-calorie sweetener?
So here's another piece of information.
If we will offer them water and we will turn on the cells,
the animal will drink the water as if it will be sugar,
like it will be appetizing.
Even though it's just plain water.
Yes, and what is becoming very obvious
is that the gut has this sense at the most basic level.
What the senses are doing is calculating a couple of things
one is
in the Salience of the stimulus is like how intense is the stimulus and the other one is the valence of the stimulus is a
pleasurable or painful, so to speak, in like broad terms?
And I say this because on the pain side, Professor David Julius, Professor Holly Ingram, Jim
Byra at UCSF, they have done some beautiful work demonstrating that there are these serotonin
releasing cells, specifically in the colon, they have focus in
the colon, that they couple to nerve fibers of the spinal cord.
And when they are activated, now all of a sudden they drive
what we call in the clinical realm, visceral hypersensitivity.
So they are responsible for triggering the hypersensitivity. So they are responsible for triggering the hypersensitivity of the nerve fibers, the
colonic nerve fibers, because they detect noxious stimuli and then ultimately they gate that
noxious stimuli and pass it on to the nerve fiber as in broad terms as a painful stimulus.
So is this irritable bowel syndrome?
It is, we could call it as the biological basis of what could degenerate into irritable
bowel syndrome and so on and so forth, or these chronicle GI, they call them disorders
of gut brain interactions in the clinic.
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As a neuroscientist,
I was trained to think about the neural retina,
the light sensing tissue at the back of the eye,
the cochlea, the essentially mechanosensory cells
in the inner ear that respond to sound waves,
not directly, but through a number of different transducers
and this kind of thing.
And then of course, where you are all familiar
with the skin and that it responds to pressure,
light touch, tickle, itch, et cetera.
What I'm understanding based on what you're telling me
is that all along the pathway from our mouth to our rectum,
we have sensory cells that are evaluating
the chemical constituents of the foods that we eat.
Emitting broad kind of, maybe even crude, slow signals
in the form of hormones to change our appetite,
our feelings of wellbeing,
maybe our feelings of not wellbeing,
but also sending direct signals to the brain
to drive certain types of thinking, emotions, and behavior.
What sorts of thoughts, emotions, and behaviors are foods known to evoke through this pathway
from the gut?
Because the story about your friend that had the gastric bypass and then changed the relationship
completely to the craving of or the aversion to sunny side up
eggs indicates that it's a pretty crude, as I'm describing a system to begin with, but
it ultimately converges on pretty fine scale decision making.
You order this and you avoid that.
You really like this and you really are almost nauseous at the thought of something else.
That's pretty high level decisions. It might not seem like it to most,
but it's impacting significant behavior
or impacting behavior at a significant level.
That's correct.
And when I think about that specific example
is that after there has been this rewiring of the intestine,
And after there has been this rewiring of the intestine, then now the intestine is very sensitive so to speak to the stimuli.
And when those lipids from the yolk start to enter the intestine, if that sensitivity
has changed, meaning it could have changed in how fast it reacts to the stimulus or how fast it communicates to the stimulus and how
sensitive it is to the saliency or like the strength of the stimulus.
It could communicate that, oh, what it used to be repulsive with a tiny little bit amount.
Now it is actually pleasurable with a tiny little bit of amount.
And here's a clear example.
So it has been very well, I will say that it has been documented in the clinic that
patients that undergo gastric bypass surgery, they're actually more prone.
I think that it goes from like two to seven fold.
The likelihood that they become,
and they will develop alcoholism.
Really?
Yes.
Because now the way that they describe it is like,
well, you know, either before I didn't like wine,
and then now after a few months of a surgery,
I'll have one glass of wine,
and then all of a sudden I found myself going to two, three, four, you know, and then they
will become either more sensitive.
It's still not known the entire biology, but they will become either not only more sensitive,
but more attracted to that type of stimulus.
I can't help but ask about Ozempic, Mungiro, and GLP-11 glucagon-like peptide-1 analogs, which are really out of
all the rage right now, at least for discussion.
But many, many, many millions of people are now taking this for treatment of diabetes
and for weight loss.
My understanding is that GLP-1 acts at the level of the brain, the hypothalamus, to reduce hunger,
but also at the level of the gut to give the sensation of more gastric distension. Is there
any knowledge of whether or not GLP-1 interacts with the neuropod cells and this pathway that
you're describing given what these neuropod cells do for craving or aversion?
what these neuropod cells do for craving or aversion? Yes, that's a complementary question.
And in fact, when I got into studying in this field 15 years ago,
the study among scientists in this area,
glucagon-like peptide was already very popular in the study.
In fact, in this area, people were very focused on the study of this peptide.
And they were very focused on the study of this peptide because it was one of the most potent
stimulators of insulin release in the pancreas. After gastric bypass surgery, it will actually
increase its amount in circulating levels. And there were already like some studies suggesting
that the effect of this glucagon-like peptide
it was actually not through the circulation
but more in a localized action onto nerve fibers,
especially of the vagus nerve.
So there was already like someone going
discussion about this. And certainly some of these enteroendocrine cells, these neuroendocrine cells particularly
at least in animals I think is more distal and in the digestive tract that they do release this glucagon-like peptide 1 in response to primarily
like all of the macronutrients, but primarily sugar.
And then these glucagon-like peptide 1 will act on specific receptors of the nerve terminals
and then will trigger some of the behaviors.
It's also thought that it acts at the level of the brainstem.
And what it will potentiate is the reduction of appetite.
So I say that this is a complementary question because what is happening
in the first few milliseconds is the actual choice and the actual feeling
of how you feel about food.
And what is happening in the minutes to hours later
is the amount, how much you can eat, right?
And when you should stop, because after four hours,
you're gonna come back and feel again,
the tickling of the gut, because the gut starts
to churn again and it starts to call for food.
Remember it has to feed two giant organisms,
the host itself,
but also the microbes that are inside, right?
So it has to keep, so to speak, that hunger going every four hours or so, right?
So that's why the hormones are more acting on the cyclical circadian way, but the transmitters are acting in this very fast responsive way
of the precise stimuli in specific regions of the gastrointestinal tract.
So these neuroendocrine cells are releasing GLP-1 or responding to GLP-1?
They're releasing GLP-1.
They're releasing GLP-1 to shut down,
transiently shut down hunger.
And probably there is some interaction between the cells
that they are having, you know,
the technical term is autocring,
or they are having like paracring between the cells,
you know, neuromodulation.
But primarily, let's say they respond to the stimulus
and release GLP-1 onto the nerve fiber
I have a theory for which I have no direct data, but I'd like your thoughts on
Having spoken to a lot of people that work on nutrition, but also
gut brain access today and
microbiome in previous episodes
that one of the key things that a
human learns,
somewhat unconsciously, but also consciously, is the relationship between a given food,
which macronutrients it contains,
the ratios of carbohydrate, protein, and fat,
the taste of that food, the amount of that food
translated into calories calories but also physical
volume and then the micronutrients.
Why do I say this?
Well, there are a growing number of studies showing that the ingestion of highly processed
food leads to the intake of excess calories or more calories than if one consumes foods
in their more natural form.
Single ingredient foods or two ingredient foods are very different than a food that
has a bunch of different things in it.
It seems to me that if we were to look back into our evolution, sure, people were making
stews and soups and things for a long time.
Presumably the sandwich came about through either desire for convenience or taste or
both, putting meats, protein in between two pieces of bread,
something of that sort, by definition of a sandwich,
maybe some vegetables in there as well, some cheese,
but that what this whole pathway along the gut
is trying to do, it seems, is to deconstruct
what's coming in, what's here, and shaping choices, as you mentioned, about
food choice, including the amount of food to further consume, and whether or not to
return to that food or to avoid it.
At the extremes, it seems pretty straightforward.
This is a very classically described case.
You go and you have the kung pao shrimp, or you have the lentil soup at a given
place and a few hours later you don't feel right, start some sweating, some gastric distress,
and you develop a pretty broader version to that food or maybe even the entire meal, maybe
the restaurant, maybe even that entire type of cuisine, depending on how much of a lump
or versus a splitter you are, as we say in science, right?
How much you make a kind of large bin decisions
or fine bin decisions.
This is nerd speak for saying, you know,
do you go back to the same restaurant
but order something different?
Or do you just decide to never go back again?
But that's a pretty extreme case, right?
The other extreme would be you eat a food, it's delicious.
You feel wonderful. The restaurant, the people, it's wonderful. And you crave more of that food, right? The other extreme would be you eat a food, it's delicious, you feel wonderful, the restaurant, the people,
it's wonderful, and you crave more of that food, okay?
There's all the contextual stuff too.
But what we really are talking about here
is how one navigates this whole landscape
of what to put into one's body in terms of nutrition,
and trying to understand how that's impacting everything
from how we feel right away, how it tastes,
whether or not we conceive it as good or bad for us,
whether or not we think it's impacting
our body composition and health
in ways that we want or don't want.
I mean, it's pretty complex stuff, right?
This is at least as complex as going to
a Metropolitan Museum of Art and looking at a painting and trying to evaluate whether or not you really like that painting or not.
In fact, it's probably much sense of a very elaborate kind.
So you just touched on an entire realm of a topic,
which is one of my favorite topics,
because at some point, you know,
as scientists, we travel the world.
And it started to become very obvious to me that wherever I went, we sold this issue of
food in a very similar way.
Whether it's a tortilla or two pieces of bread, which is another way of a tortilla, you have
your carbs.
And then you add a little bit of meat or a mushroom and now you have your carbs. And then you add a little bit of meat or a mushroom,
and now you have your protein.
Or fish or chicken.
Or fish or chicken.
The carnivores will say mushrooms not a protein,
the vegans will say mushroom, beans, lentils, great protein.
We're not here to resolve that debate.
Do as you choose.
And then you add the lettuce,
or the vegetables. And here's the first stop in that discussion because this is fascinating.
There are some recent work showing that if you remove the protein from a diet, the animal swallows that meal.
They get evaluates that there is no protein in there and it stops eating that meal.
Wow.
So this is like ordering the vegetarian taco or burrito or sandwich, and then avoiding that particular taco or sandwich thereafter
because it lacks protein.
Because it lacks protein.
Okay.
So foods that lack animal-based proteins tend to be avoided going forward.
So here's the second part of that.
No.
And in fact, if the protein is low, not completely absent. If the protein is low,
the animal consumes more of the diet because it's trying to compensate for the lack of
protein. And obviously, if it has sugars or fats that are more pleasurable, it keeps eating
that meal, right?
I see. If the protein is completely absent, the animal avoids that diet unless that diet is very
rich in dietary fibers.
And the study that I saw, which I thought was fascinating, is that because somehow the microorganisms in the
digestive tract, if they have enough highly digestible fiber, now they turn on the ability
to synthesize essential amino acids.
Really?
Yes.
So our gut, meaning the neurons in our gut, are essentially waiting for, hoping, we'll give
them a consciousness, proteins from animal sources.
That's correct.
If those animal proteins arrive in the form of meat, fish, eggs, et cetera, the cells
signal to the brain craving more of those foods until satiety is reached.
But in the absence of that protein, the animal quickly learns, the person quickly learns
to avoid that particular food unless there's fiber in it, in which case these gut cells
are able to now synthesize the essential amino acids-
The microorganisms.
Excuse me, the microorganisms of the gut.
Here we're talking about the microbiome now, can synthesize
the essential amino acids that ordinarily would come from the meat, chicken, fish or
eggs.
That's right.
Wow.
I'm an omnivore.
I love meat, high quality meat, but I also love vegetables, fruits and starches of certain
kinds.
But I have friends who are vegetarian vegan.
Many of them eat a vegetarian vegan diet that includes a lot of fiber.
And you're saying that the fiber itself can trigger the gut microbiome to synthesize the
essential amino acids that ordinarily would come from meat. But you also said, if I recall,
that if there's a small amount of protein,
so not zero protein, but a small amount of protein in there,
then we crave more of that food
in order to try and get that protein.
Compensate.
Very interesting, because this is the first thing
that to me squares the argument based on the observation
that, or the hypothesis that we are essentially
amino acid foraging machines and that complete proteins in the form of meat, fish, chicken,
eggs, et cetera, there are those that argue those are the quote unquote best forms of
protein, the most complete forms.
But there are many vegetarians and vegans who seem to thrive on a vegetarian vegan diet.
You're telling me that perhaps their body is their gut microbiome is compensating for the lack of whole animal protein
That's right, and the people who are trying to limit their meat intake are what hungrier in general?
So you're better off either
Indulging it or avoiding it but not having a small amount of it
Is that the idea the idea is that the the the body or the gut will be able to detect that and then we'll try
to compensate, right?
I see.
And these I actually learned recently from a friend, Laura Duval with Columbia, who works
and does some beautiful work on mosquitoes and how it is that they feed on blood.
She came for the Gastronauts series.
Is she from Leslie Valsall?
Yeah.
Valsall, yeah.
And what I learned is that when the mosquitoes are not reproducing, they can leave off ATP,
which is the energy molecule, right?
But they cannot lay eggs.
They need the protein in order to be able to lay eggs.
Otherwise, the mosquitoes cannot lay the egg.
So this leaves us with a picture of the gut-sensing cells, these neuropod cells, as exquisitely
sensitive to amino acid content in our foods, which makes perfect
sense to me.
And it has not been published or demonstrated yet.
Sure.
We're now in the realm of new incoming data.
We want to highlight this, bracket it, boldface and underline it as we're now at the cutting
edge of what may be coming.
That's right.
Observation.
But nonetheless, very interesting.
But there is this fairly longstanding hypothesis that we are foraging for essential amino acids
because they are the building blocks of so many important things in the brain and body.
And in fact, there is evidence that Professor Steven Simpson in Australia in the Nutrition Research Institute at Sydney University, he is main proponent
of these protein leverage hypothesis.
You know that in fact, a protein is the most associating macronutrient.
So that has been established.
And that's why normally we have focused on sugars and fats, but we have neglected a little
bit on the protein because it's not as pleasurable as on sugars and fats, but we have neglected a little bit on the
protein because it's not as pleasurable as the sugars or fats.
But what is fascinating is that it is the most satiating nutrient.
And as you know, it's like the most limiting and also like even commercially is the most
expensive right now.
Yeah.
I certainly have had the experience of at one time in my life really enjoying and even
craving sweet foods, desserts and sugars and things of that sort.
And I noticed that over time, if I eat sufficient amounts of meat, chicken, eggs, fish, which
is not to say that I consume excess amounts of them, that my sugar cravings go way, way
down.
That's just my personal experience, but I know it's an experience that family members of mine
and others share as well.
But I promise you that this was a fun topic, right?
I couldn't, we couldn't stop at like just layer number one.
Layer number two is that in agriculture,
we have this instinct to plant,
plants that complement each other.
Like for instance, a classic, especially native,
among native communities is called like the three Marys.
I believe is a pumpkins on some type of fibers
with corn, carbohydrates and beans.
So in purely plant-based diets, there's an effort to get the fiber, the sugar, and the
amino acids.
That's right.
And I grew up in a farm.
My parents had farms, and I remember when they would plant, they would also throw in
there the beans, and the beans would wrap around the corn.
And it just seemed so natural, and that's what you will do, because that's what you
learn to do.
But if you think about it, it's an instinct that we have developed even agriculturally
and probably in the subconscious to cultivate them in such a way or perhaps the plants taught
us how to cultivate them in such a way that now when we put them in the plate, it just
makes sense at the nutritional level.
Because if you think about it, every time that we go to eat, how is it that we arrange
that plate, right?
There is some rice, which is very deficient in some essential amino acids, but it's rich
in carbohydrates, right?
It has some beans, right?
And then there's some lettuce, you know, and sometimes we have like for omnivores,
people would put meat or you would put other types
of protein in there, right?
And certainly it varies by culture, time of year,
food availability and things of that sort.
As long as we're talking about your upbringing,
you have a fascinating story.
So maybe we could discuss that for a few minutes.
Where were you born?
I was born in the Amazonia of Ecuador, a small town called El Chaco in Ecuador.
It's on the slopes of the eastern slopes of the Andes on the way to the Amazonia in the
Napa province. Coincidentally, it was like through the path
from where Francisco de Orellana in 1542 marched
on its way to the discovery of the Amazon.
It actually passed through a trail that later on reading,
I realized that native people had all of these trails
between the Amazonia and the Andes
and the coastal line for thousands of years.
You grew up in a very rural place.
Yes. The oil had been detected in the 1920s in Ecuador. It was first explored in 1964 in the first
1964 in the first oil well was in a town called Laiguagrio, which now is only like three or four hours from the town where I grew up.
But at that time, it was like eight hours, the roads were not good.
And the first road passed through it in 1974, I was born in 1983, but I remember that we used to have like a giant diesel engine
that will give us light electricity only from 7 to 9 p.m. You know, I remember when my father bought the first color television in the town and then neighbors
will come to our living room and then we will watch movies.
Wow.
This was in the 80s.
That was in the 80s, right?
Such an interesting upbringing.
So did you eat a purely vegetarian diet or you ate meats as well?
Where did those meats come from, if you did?
Primarily from cattle, goats, sheep.
So how do you go from the Amazon to a study of nutrition and ultimately neuroscience?
Yeah, that's the question, right?
The deeper I go, the more I question this.
I used to think that, oh, it was very simple, you know, like when I was specifically when
I was 11 years old, my father, he was born in 1932.
By 19, he lost his father, my grandfather,
when he was six years old.
Then he was given away and he had to go
and like build his life.
He was a very successful entrepreneur.
But in the process, he had made a lot of friends
and acquaintances.
So when I was 11 years old, I remember specifically
that a friend of his who was in the special forces
stopped by our home because that was the main road that we go into the Amazon jungle where
the folks in the special forces in the military will be trained. And he stopped by and said
like, hey Rogelio, like what are you going to do with Diego? You know, like I think that
it is about time that, you know, I think that you should send him to the military school.
And I remember in a matter of like literally a couple of weeks or three weeks, I had given
the, taken the tests and I was accepted into the military school and then I ended up in
a military school and this was the, at that time it was the premier military school in
the country.
That alone it was, with years you start to understand the context in which you developed.
Because it was a very interesting context for a child.
Like, just to give you an idea, this school had the first and the only zoo in the country.
So from my classroom, I would literally look at the lions.
And then I think that was by the second year
that I was in the school, second or third year.
Because the city started to grow,
and then the military school was wrong.
And then they separated the higher education
for military officers.
They separated them, and they put them in a different place.
But that zoo actually became the first zoo of the capital of Quito.
So you had a zoo with lions at your school.
Yes.
And you said you could see the lions in your classroom.
And they could see you presumably.
I probably know them.
But they were like far, right?
I assume they could see you.
Lion vision is pretty good.
I don't know what the resolution is, but I'm guessing that their vision is.
Yeah, they definitely use their olfaction,
but they are site-based hunters as well.
But I have specifically one memory, like climbing up,
I think was like from the,
because we had an Olympic pool
and we had all of these events.
The soccer field was the field where the national team will go and train on because
they didn't have their own training grounds.
Later on, they had their own training ground.
But that was something that you just grow into it, right?
But it was with the years and now especially
that I get to reflect on it.
I was extremely fortunate through that experience
and that education.
And now I'm here sharing some of the story.
And hopefully through that inspiring some people,
especially young people, that would like to go
and chase their dreams.
So you went to military school in Ecuador.
You graduated and you decided to go to school in the state?
So in the military school, they will select the top cadets, like I think it was the top
10%, and they will select them and they will put them through a special training.
So you have, essentially, didn't have like what was a normal summer vacation, you know.
I would go into military training.
So for me, it was going to be very, not easy,
but relatively straightforward to transition
into Officers Academy, right?
Like, do four more years, like West Point here,
and then, like, become an officer, right?
In fact, I had a Reserves Officer degree when I graduated.
But two years before graduating, a friend of mine who he preferred other types of careers,
he said like, you're not going to become a military, right?
You're not going to go into the military.
And he said, you should probably study something that will help your parents. And then I said,
what will that be? And he said, like, perhaps agriculture. And I didn't think at that time,
it didn't dawn on me that, you know, people can study for agriculture and agriculture
is like the base of food for all of us, right?
And then I said, where?
And then he mentioned for the first time
this university in Zamorano,
which was founded with some funds that were donated
by the founder of the Standard Fruit Company,
which eventually became, I think,
Chiquita Banana, Zamzemoray.
And that is an oasis that is in Honduras,
outside of Tegucigalpa.
So he's a boarding school, you wear a uniform.
So it was kind of like military, it was very strict.
You cannot accumulate more than 12 demerits,
otherwise they will send you home.
How do you get a demerit?
You show up two minutes late to work in the morning at 6 a.m. in the field and then you
just get to...
Two minutes late, one demerit.
Twelve of those, you're out.
Two demerits.
Two demerits, you're out.
Yeah, you get a...
We used to get a...
They will check your room.
So, for instance, a guest like you, if you will go there, like they will give you...
Every Wednesday they had at 7 p.pm, they will check your room,
but like very meticulously, right? And if they found a little bit of dust on the window
or something to the merits.
And you're going home.
If you accumulate enough, you will go home, right? So it really forms character, right?
And then-
Do you do that with your kids?
No. I think that I have become very-
Do they make their beds?
They do make their beds.
Yeah.
Yeah.
Okay.
But that was the context.
And it was then where I learned about two things.
One is where this idea of getting a PhD, because I noticed that most of the leaders will have
a PhD, most of the leaders in the university.
And I realized in the United States is one of the training grounds, main training grounds
for PhDs.
And the other one was nutrition.
I was a little bit more keen on perhaps going into veterinary school.
And then I had an experience in a dairy farm in California where I learned the value of
nutrition.
There was more prophylactic rather than a palliative
or like treating the cow, right?
And that kind of convinced me like to look for a training
in nutrition.
And then a friend of mine, the late Abel Garnath,
he was able to connect me with some friends
and my mentor at North Carolina State University.
And that's where I ended up doing my PhD in nutrition, and that's where like the career
became.
And then maybe another detail in there is that I was so excited about taking, that's
where I took my first physiology class.
And all of a sudden I realized that in a way the body was like a machine, right?
Like obviously it's a limited way of thinking, but the body was like a machine.
And one of the professors was a neuroscientist.
And I took two physiologists, two human physiologists with him.
And I was just thrilled by when he will explain how is it that in the synaptic terminal there
were these vesicles that had like these proteins that will walk the is it that in the synaptic terminal there were these
vesicles that had like these proteins that will walk the vesicle in the presynaptic active
zone and that's how we make movement, you know, something like that.
And I guess I kept that in the background of my head and when I had the opportunity
to work in the gut, I applied that.
So you were enchanted by the nervous system.
Yes. Yeah, as I was too.
Nothing to me is more spectacular than the realization that we are made up of these little
tiny cells, many different types, but that the neurons essentially govern our entire
experience of life.
It's just amazing.
Well, that's quite a journey from the Amazon to, well, this table and much more, of course.
Thank you for sharing that.
So you grew up in a, let's call it a plant rich environment,
the Amazon, at least from the pictures I've seen.
That's correct.
Let's talk about plants, botanicals, and the idea that maybe plants, for lack of a better
way to put it, have a certain intelligence or a composition that is not random with respect
to our interactions with them, right?
You described how agriculture in some places
has evolved to include and ensure
the different macronutrients
and essential amino acid intake,
even in the absence of animal proteins.
Is it the pumpkin or the squash, the corn and the beans?
What are your thoughts on plants,
perhaps from the Amazon, but elsewhere too, and their
capacity to have things in them, chemicals that can be good for us at the level of the
gut, but perhaps at the level of the brain or other organs as well?
How do you think about plants these days?
The first thing you mentioned there, like intelligence, right?
I don't know if that exact terminology applies,
but I do like this word wisdom
because it's reflective experience, right?
And I say reflective experience
because somehow we are going over the experience.
And plants have been many more millions years of age
on earth than any other animal, right?
Therefore, they have had way more time
to actually experience the ground.
So to think that they don't know what is going on,
I think it's a little bit perhaps naive is the word. I went to the main court of these Mayan ruins
of Copan, the junction between Honduras and Guatemala. This was a very special city of
the Mayans. And in the main court, you see like all of these estellas which are like the main
stones of the kings of several dynasties and at the top of one of the stairs on these pyramids there is this giant Seva tree which is like 650 years old, something like that.
So that tree was there before the Spaniards landed in there,
when the Mayans perhaps were still celebrating things,
or perhaps right after.
So imagine how much information that organism has in there.
And we will be able to just tap somehow into that information, like climate, fluctuations,
organisms, interactions, movements, I mean, like so many different things, right?
Like that right now, I don't think that we even have the language of being able to understand
at the organismic level of how much information that is stored
in one single one of those organisms.
But then think about a chloroplast, for instance, or like one of the photosynthetic organelles
inside of the cells.
How is it that they have been shaped for hundreds of years in those organisms, right?
And I think that perhaps in the future, this is more of a sci-fi right now, but perhaps
in the future we will be able to harvest that type of wisdom.
We will be able to understand a lot about the place or the earth that we live in.
That's point number one.
Point number two is that these plants have been interacting
and we have been interacting with plants
for hundreds of years, right?
And obviously we are a consequence of the environment,
right, like here driving in LA or driving in a major city
for some of us,
it's just like second nature, right? But if you go into a jungle,
then all of a sudden it will not be the same thing, right?
But for somebody that has been in the jungle
for hundreds of years, now all of a sudden
they are able to describe with such a sensitivity
of like how it is that the jungle is,
the makeup of the jungle is in there.
I've seen native people walking through the jungle
without shoes and right before stepping on a leaf,
stopping and then pointing out like,
look underneath that leaf and then like lifting it out
and then a tarantula right there.
Like how do you even make sense of that?
Like I don't have the sensory acuity or the wisdom to be able to figure that out.
But they do, right?
And certainly that is just a level of sensory perception that I am not equipped with.
But I do think that there's quite a bit of that interaction in there to learn.
And then of course, not only for food, but also for medicine, for textiles, and for many
other functions.
These plants have been part of the ecosystem of how these people navigate their world,
all the way from making a canoe to making a backpack to carry fish from the river into the house, right?
How do you think we evolved food choices
and flavor preferences?
I imagine humans that existed long before us,
being hungry, the gut starts rumbling,
and there are all these plants everywhere, some nuts and some berries
and things and so they had presumably no choice but to consume them and decide at the level
of the mouth like that's bitter, no, that's not good, maybe eventually cook those and
see if that changes the relationship.
I'm thinking raw acorn versus cooked acorn, you know?
But that ultimately there was a lot of trial and error and that these neuropod cells, which
surely existed for a very long time prior to us, played a key role in discerning what's
in these plants, barks, roots, nuts, berries, we're setting aside meats for the moment and other animal proteins
and making decisions about what's nutritious, what is safe, what is not safe.
That's a pretty complex process given that some things might taste okay, go down okay,
but then you run into serious trouble later.
Given the critical importance of ingesting sufficient amounts of macronutrients
and the need for micronutrients to survive
on a day-to-day basis, much less reproduce, propagate,
one imagines that this is almost as essential as breathing
and that this path in our nervous system
of the neuropod cells to the brain
for sake of decision-making of yum, yuck, or meh
is perhaps one of the most important core functions
of the nervous system once you get past the elements
that control breathing, heart rate,
you know, temperature regulation, things of that sort.
I see it as among the senses, it's at least as important as vision and perhaps more in
terms of making sure that we survive from day to day.
That's correct.
And here's where I think there is a large vacuum in biology. If I would be with my biological, my training
in biology, if I would put my hat of the training in biology, I wouldn't be able to explain
much of like how is it that we figure it out because even if you just go to a botanical garden here in the city, it will be really hard to
figure out what plant is for what, right?
What's safe to eat, what's not?
What is safe to eat, what is not?
Do you need to cook it or not?
Maybe the cacti, you are able to figure that out by touch, right?
So from the biological perspective, I think that there is quite a bit in there to explore
and to learn.
There is some very interesting work from the anthropological perspective.
So, anthropologists and botanists that were studying the plants were exploring the jungles,
not only the Amazon, but Borneo, Sri Lanka, and so on and so forth, and studying the interaction
of native people with the plants.
And if going through the literature, that literature, there is a pattern that emerges
in like the native people, they talk about how it is that they actually learn from the
plants, that the plants were the ones that were to teach them.
You know, so that's why I said from the biological perspective,
how can we reconcile that?
I think that there is still quite a bit to learn.
What does that mean to learn from the plants?
I mean, there's something that intuitively makes sense
when you say that.
I've heard about looking at plants as teachers,
about the local environment.
When they're open, they're light sensing,
when they're closed.
But in terms of translating some of that to
how humans have learned to navigate given environments,
navigate meaning sort of thrive in those environments,
how do we go about that?
Does it mean taking plants, grinding them up, and figuring out their constituent parts?
Or is that too reductionist?
Is that going to leave us with a parts list that doesn't mean anything?
Sort of like if I splayed out all the pieces of a car or an airplane in front of us, it
doesn't really tell us anything about that except what parts make up the thing that flies? Yes, and that's why I said like this is more on the anthropological studies that have,
you know, especially from scientists that have gone there and learned the language,
live with the natives as natives, you know, and then start to understand the dynamic of
their culture and their interactions. Then that's when, like for instance,
how it is that they classify plants.
The way that they classify plants is like several levels
more richer than our classification,
our scientific classification by the two name system
or the variety, right?
Like for instance, they take into account
not only the flavor, but also the shape,
the location, how they interact over the year,
how they react over the year.
For instance, there is this beautiful plant
that people call it the leaps plant.
I don't know if you have, but if you Google it,
you will see it.
It's like lips. Literally like lips. It has like these red, beautiful lips like the plant. It just looks
like lips. And then people use it for pain, for some rashes, skin rashes, and also like
in some rituals and like most of these plants, the way that the natives interact with the
plants is in a sacred level, you know, there is this respect for the plant, right?
So yeah, I think that biologically I think that there is quite a bit in there to understand
and explore and define.
I do agree with you that like just thinking
about grinding it up and like just putting it in a,
in a tip perhaps is to a reductionist.
It could be a beginning of a understanding,
but it is reductionist.
Seems like nowadays in the field of biomedical research
and clinical research that there's a lot of interest
in plant-based psychedelics.
research that there's a lot of interest in plant-based psychedelics. You know, LSD from ergot and psilocybin, mushroom and so on and so forth.
Ayahuasca, iboga. So it seems like science and plants have merged at that
level in terms of clinical implications. Of course, there are entire fields of plant biology
that are extremely important.
I think most people probably don't realize this,
but a lot of what we understand about circadian rhythms
grew, no pun intended, out of our understanding
of plant circadian rhythms first,
and then it was translated to mammals,
a beautiful work by Steve Kay and others,
seeing the circadian rhythms in leaf opening
and orientation of the whole plant
and other features of plants that are mirrored
by the changes in arousal level in mammals, including us,
which is why I'm always telling people
to get sunlight in their eyes early in the day
and to avoid bright light in the evening and nighttime.
So what are your thoughts on plants early in the day and to avoid bright light in the evening and nighttime.
So what are your thoughts on plants as a source of medicine, psychedelic or otherwise?
I think that, well, traditionally,
that's where medicine was developed from.
I was at the Oxford Botanical Gardens last year
with the family, and we went into the gardens
and they have a beautiful garden.
It was established in 1621.
I think it was the first botanical gardens in England.
And they have a beautiful medicinal plant collection.
And there was this very humble,
what are we, little sign with a description in there that said in there that about 80% of medicine
still comes straight from plants.
Really?
Yes.
And if you think about it, it kind of makes sense, right?
Because when we think about the medicines that we have been able to develop, which have
been phenomenal, especially for certain chronic diseases.
But we don't have like a broad repertoire of it, right?
So I think that has been obviously a great advance in our society that we have been able
to identify the molecules, synthesize the molecules, package the molecules, render them bioavailable
in specific sites.
And I think that when we are able to couple that
with the rest of the molecules that the plants,
through their, I keep saying their wisdom,
because somehow they develop their ability
to have not only one molecule,
but like a combination of other things
that will provide the full experience of
of the plant right. For instance a yerba mate, you know, is not only caffeine right because it's
very different than a shot of espresso you know if you take the whole thing it not only gives you
energy but it gives you a full range of an experience that is specific to the yerba mate, which is a leaf, right?
Yeah, it's a distinctly different subjective experience than coffee.
I enjoy both coffee and espresso and yerba mate.
You were the one who introduced me to guayusa.
Guayusa.
Guayusa.
Yeah, which is a causing of yerba mate because yerba mate is Ilex paraguagenesis.
Guayusa is Ilex guayusa.
And it's not as bitter as mate, but it has almost as much caffeine as coffee and it has
antioxidants and other compounds, which give you these very smooth experience. So natives in the Amazon, they take a drink of a Guayusa every morning around 4 a.m.,
between 4 and 6 a.m.
They wake up early.
They actually call it, yes.
It was like Jocko Willink early.
Some people understand that joke.
He wakes up every morning and he posts a picture of his Casio watch.
Yep. And he's already training 430. So no Guayusa required for Jaco.
And they call it the Guaiza Upina Ura, the hour of the Guayusa. And it's a ritualistic
drinking of the Guayusa in the morning and where they talk as a family
of the issues that they have had the days before or the weeks before, like either with
other communities within the family if they have to represent or reprimand one of the
children or talk to them about like some mistakes that they are making.
And then they plan the full day of activities
by drinking a waiusa.
And around 5.30, because they will boil the waiusa, right?
And they keep boiling the waiusa,
and they just keep adding water to it.
And then around 5, 5.30, then they
will have what is called a bowl of chonta.
And chonta is this pound date,
very rich in lipids and fibers.
So they will have the guayusa
because the guayusa they say that gives them energy,
it heals any pain,
it shuts down appetite so they will eat at like 3 p.m., shuts down or modulates appetite.
As does Yobromate.
That's one of the more potent effects actually
of mate in Guayusa is a mild to moderate appetite suppression.
And then if you combine that to chonta,
which gives you the lipids,
and then it's like a full meal until 3 p.m., and then they go and work in the fields.
Interesting.
So they're essentially starting the day with hydration, caffeine, and then they what in
some circles they call fat fasting, meaning consuming lipids in order to stave off hunger.
I mean, it's the highest density source of calories among macronutrients.
And it's a vegetable-based diet, I guess you're right.
Are they a healthy culture?
Do they live a long time?
I am not the...
I should probably do more reading that.
I'm not well-educated in what are the studies that have follow up on the,
you know, in the health status of the communities.
But what I can tell you is that at least colloquially,
I will say that diabetes, those type of issues
are not as prevalent,
but they do have, obviously, through, like, social exposure,
they have other things, you know?
Fascinating.
This morning ritual of conversation
about family and culture and what's needed,
planning the day.
We had on this podcast as a guest, Dr. Sachin Panda,
who is at the Salk Institute for Biological Studies,
often known for his work on intermittent fasting,
time-restricted feeding,
but also has done beautiful circadian biology.
And he talked about the use of fireside chats,
not the sort on stage, but gathering around fire at night
is something that has existed in many cultures
where people reflect on the previous day
and discuss issues, social and work issues,
and sort of dissect what's happened and talk. And it's about
building and repairing relationships. Sounds like in this, is it a, what is this group? Is it a rule?
Is this a- Yeah, native community. Because there are like about 70 or so communities that have been
documented in the Amazonia with their own
language, with their own traditions, and many of them share the same type of traditions.
And if you think about it, like a podcast is one way of an evolution of that conversation,
right?
Like where we can have this extended conversation and get these more primordial things, the
ones that we have them in the
prefrontal cortex right away and like discuss about like, well, you know, this discovers
these identifications.
But then we get to the part of like, what does it mean for the whole community?
Yeah, there's doing, there's reflecting, and then there's resting and recovering, right?
And there is something about like living death for the next generation, right?
Yeah, passing on of lessons, but better learn from the mistakes and successes of others
if you can, as you go forward.
Very interesting.
If we could, I'd like to now return to the biology, the nervous system.
Absolutely.
And thank you for that voyage
through some of your background in Ecuador.
Fascinating.
I do for a mug of guayusa.
Sometimes I'll mix the two,
the loose leaf yerba mate and the guayusa.
And as you said, what's-
How does it feel?
I really like it.
Most of the time it's loose leaf yerba mate
or cobreed yerba mate, but sometimes I'll
mix in the guayusa leaves.
And what I do like, as you mentioned, is you can continue to pour water over them for many
hours and it tastes different as the time goes on.
And my guess is you're extracting different things from it in different concentrations
as time goes on.
I realize it's not a precise science.
It's interesting today we're talking about very precise neurons and methods of tracing
neurons and sensing of specific amino acids and lipids at the level of the gut.
Then we're also going to more macroscopic view, a broader scale view of the plants having
many things that need to coexist in certain
ratios that the plants have evolved to create for us.
So we're sort of straddling both ends of the continuum.
And if I could fit in their story, no long ago I visited a friend, a native friend in
a nearby town and he produces some of the best chocolate,
what I will say, in the planet, you know,
because actually the plants of theobroma cacao was recently
documented, there was a paper in Science not long ago
that it was domesticated in Ecuador near where I grew up
and they have done some tracing and genetic tracing. domesticated in Ecuador, near where I grew up.
They have done some tracing and genetic tracing.
So he produces some of the best chocolate.
Literally, he harvested it in there,
and then he roasted, grinded, and then he
prepared it for us in there.
The Swiss are saying, or the Belgians,
are claiming the best chocolate.
But now we know Ecuador is the place for the best chocolate.
I think I just got a lot of Swiss and Belgians angry at me
for saying that, but do they have a very dark variety?
I like the extreme dark varieties, 95%.
Even 100% chocolate, if it comes from a really quality
source can be absolutely delicious.
It's like milk straight from the cow, right?
Like, and what he did is he said, Diego,
you have to try it with guayusa.
And he mixed the chocolate with guayusa.
As a drink?
Like as a drink.
Boy, that will give you wings.
Guayusa hot chocolate.
Yes.
And it's a very smooth experience, right?
Like you're mixing this tea, which is for energy,
with chocolate of the best quality.
So we're not talking about eating chocolate and drinking
tea.
We're talking about melting the chocolate in the Guayusa.
It was something like one of a kind.
Then, of course, I couldn't sleep until like 3 a.m. I think.
Right, there's something to do,
maybe this is why these groups drink the Guayusa
so early in the day.
That's right.
Yeah, and I have to imagine I would need caffeine
at 4 a.m., 5 a.m., otherwise I'd be falling back asleep.
So, yeah.
So, back in the gut and nervous system,
in particular within the brain,
we haven't talked about the brain so much.
We can't talk.
So the information from the gut is sent
via these neuropod cells up to,
you mentioned the nodose ganglion,
such a cool name for a brain.
And a ganglion in this instance is an aggregate of neurons.
So it's like a batch of neurons
that then send a connection into the brain.
What brain areas do they send it to?
And maybe we could describe these by name,
but also by function,
what they generally are responsible for.
And probably should be prefaced with,
ultimately will go to the entire brain.
Right, everything ultimately connects everything
It's like Google Maps everything connects to everything but but what are some of the primary?
recipients
First hubs
Into of sensory integration are in the brain stem, you know
And for instance the nucleus tractus solitarius is in a specific
region within the brain.
The caudal is one area.
And NTS, for those that don't know, is involved in regulating hunger and appetite.
That's correct.
Other functions perhaps, but like for instance, that seems to be an area of sensory integration
for nutrients.
And when we say drives hunger or appetite, sensory integration for nutrients,
I mean, what would be great is if, you know, people could understand, you know,
the language of the nervous system is chemical and electrical.
So when these neurons are active, we tend to crave certain foods, you know,
seek them literally, go to the refrigerator, among the different choices, go to that thing
and select that and put it into our mouth.
So presumably it's driving reward systems, motor systems.
I mean, what we call hunger and appetite
is really a kind of a domino effect
of a lot of different brain circuits.
Do we know whether or not the nucleus tractus solitaris projects to the areas of the brain
involved in dopamine release and craving?
Yes.
And there has been some elegant work from several different neuroscientists in this area,
like tracking the circuitry from there onto many other different
areas.
The hypothalamus, for instance, very basic behavioral functions.
And the striatum where there is dopamine release and then there is this pleasurable sensation
and reward.
There are several other areas in there that are involved in this sensory
integration. There is quite a bit of work still to be done from, specifically from the
neuro pods. There is like some evidence that they are connecting directly to, or there
are, if you put two papers together, it's obvious that they are connecting to like some of these areas of dopamine release basal ganglia in the brain and that's why they're
causing this reinforcing effect like in the lateral hypothalamus and other
areas. I do think that ultimately there is quite a bit of a gap in like
different regions of the digestive tract.
Today we just talked about the esophagus, right?
Like the esophagus, I think that it's still, there is a little bit of work.
Perhaps I think that Steve Liberlitz has worked in that area, another great neuroscientist
doing some very fine detailed work in sensory biology. In the esophagus, there is quite
a bit of a lack of precise biology in how it is that the esophagus, the specific cells
of the esophagus are innervated or like making sense of the environment. Same thing for the
stomach and how it is that ultimately each one of those regions are feeding
into different regions of the brain.
Even then, how each one of these valves, I'm fascinated by each one of the valves that
we talked early on like the gastroesophageal splinter or the pylorus or the ileocecal junction.
Yeah, we should illustrate for people. I'm not an expert in the gut by any means,
but what Dr. Borges is referring to is that, you know, the gut, as it extends from the mouth to the rectum,
is not just a series of tubes of different diameters, but rather they have valves, chambers, and
these sphincters that cut off.
Everyone hears the word sphincter, and they always think, oh, anal sphincter, and then
they, ah, it's like elementary school, middle school humor.
But sphincters, they literally can close and open to varying extent in order to allow passage or prohibit passage from one compartment to the next,
such that certain things can take place over time in one region, like the esophagus or within the
stomach or before passing to other chambers. And so I hear you saying that critical processing is
happening at each of these chambers. The sphincters are determining how long that processing occurs and that distinct sets of
neuropod cells are likely detecting distinct qualities and quantities within the food,
chemical qualities and quantities within the food and relaying that to the brain.
That's correct.
And here's something that since we're getting into the future of this area.
And while there is not direct published evidence yet, I think that is going to be a fun area.
So the gut as the brain also generates these electrical patterns.
Those electrical patterns change depending on fasting versus
feeding and circadian rhythms. Probably cannot realize jet lag. The gut is asking you for a
burger at 3 a.m. and your brain is telling the gut, you know, can you please go to sleep, right?
So these electrical patterns, these electrical waves that are going into, that are being
propagated by the gastrointestinal tract, there are like several different cells like
the enteric neurons are coordinating these cells.
There are also these interstitial cells of Cajal.
So, Santiago Ramon y Cajal.
The greatest neurobiologist of all time.
That's right.
It was named after him.
He actually has, I think it's like in the second volume
of his classic book on the histology of the nervous system
and one of the last figures talks
about like the innervation of the villi in the intestine.
So beautiful.
For those that don't know, Cajal shared the Nobel Prize with Camila Golgi in 1906.
They together developed tools
and mapped the structure of the nervous system.
And it's fair to say that Cajal had supernatural levels
of insight into the nervous system.
He looked at the nervous systems
of so many different animals in dead specimens.
The joke, even though it's not funny,
is that many animal species entered his laboratory,
very few walked out.
But by looking at fixed specimens under the microscope
and then drawing them in select elements within them,
essentially came up with most of the major hypotheses
about how the nervous system works,
not just its structure, but neuroplasticity,
the failure of mammalian central nervous system neurons
to regenerate.
This is why after traumatic brain injury or stroke,
there's often loss of function that doesn't recover.
Sometimes it recovers, but,
and that people who have injuries younger
often can recover certain functions.
Everything from the direction of electrical flow through the nervous system, all from
looking at tissue that was not alive.
No electrophysiology, no behavioral experiments, just raw but incredible, supernatural, seemingly
levels of intuition and insight.
Amazing.
Yes.
There is some quote in one of his books that when he got invited to
one of his friends to England, I don't remember.
It was a it was a famous neuroscientist at the time in the late 1800s
that who had helped him to expose
his work to other audiences, you know, and invited him to to England.
So he said in there that it took like three months to go to that podcast, right?
Like it was a three-month trip.
So he said that he brought his microscope.
With him.
With him.
Of course.
In the room, he will be able to do some of these observations.
Yeah.
Peculiar guy. some of these observations. Yeah, peculiar guy, also known for carrying a very heavy iron umbrella in order to do
physical exercise on the way to the lab.
He was a very, very fit physical specimen.
Also purportedly, reportedly, I don't know which, pick which one, a pretty gruff person,
not terribly pleasant to be around,
ran a tight ship.
But in any event, so the cells of the gut are named after,
some of them are named after Kahal,
interstitial cells of Kahal.
Cells of Kahal.
There, you just got a waltz into some neuroscience history
but critical history.
So they have this emanating electricity, right?
And so far, these...
And it seems like the sphincters modulate the emanation of this electricity.
Oh, like an instrument.
Yeah.
And you probably think like that because the intestine...
And maybe here we get a little bit even deeper into these. And I read some work from a philosopher in the UK who was,
and I'm going to paraphrase it very largely, you know,
so please don't quote me.
But it's something along the lines
that if we are what we eat, the place where food becomes us
and we become food, it should be the intestine, right?
Because that is where food is actually absorbed, right?
So that is a very fascinating point.
Number two is that the food enters us at a frequency that it will modulate the entire
body, right?
Therefore, like the body through these electricity, these electrical
waves should be in sync with also the electricity of the entire nervous
system. So I think that here's where in the future I think that there's going to
be a fascinating realm of understanding how it is that these waves of the body
and the brain are synchronized with each other.
Because as we know, like for instance, sometimes when we don't, we're hungry, we become hungry,
you know, like we become irritated by the fact that we don't have food and perhaps
it's this dissonance in the emanation of the electrical waves between the digestive tract
and the emanation of the electrical waves between the digestive tract and the nervous system.
So I think that that is just like one of the realms
of how it is that the brain is connected to the gut
at a more organ to organ level
to be able to make us function ultimately, right?
Because that's how we are integrating the outside world,
the food, into our entire system
so we can maintain the entire organism.
Well, certainly our level of alertness
is linked to our level of anticipation,
and a lot of our food anticipation
impacts our levels of arousal, aka alertness.
So as you mentioned in the, we're a diurnal species.
So in the middle of the night, it's unusual to get hungry.
Right, a lot of these pathways are shut down.
Digestion is happening at different rates
and typically our appetite is greater during the day
than it is in the middle of the night.
That's right.
But in addition to that, you know, it makes good sense to me that what is going on at
the level of our gut is going to tell the brain, did we get enough nutrients from the
previous day?
Are we in a place of abundance?
There's also the psychological aspect of gut sensing, and we haven't really touched on
that.
What are your thoughts as both a scientist and a human
with a gut brain access on this notion of a kind of gut
intuition?
You meet certain people and it sort of relaxes and warms you
and you want to get to know them, or other people for
whatever reason, you just feel like, I don't know,
something doesn't feel quite right.
That we can sense things at the level of the body that inform
our brain, and no one really understands that process. doesn't feel quite right, that we can sense things at the level of the body that inform
our brain.
And no one really understands that process yet.
But we do know that the vagus nerve, which is a multi-pronged pathway, big pathway, it's
probably its own major branch of the nervous system really, is sending bidirectional communication
between brain and body.
And presumably when we're around somebody or something that doesn't, quote unquote,
feel right, the vagus is involved.
A few interesting things in that area.
I mean, in the work of Carl Jung talks about it, about the subconscious and how it is that we're accumulating all of these experiences
that we have been passing through in life.
It's not that they are not a story anymore.
It's just that they are back in the subconscious, right?
And then ultimately they become part of this
so-called intuition, right?
Like we have this gut feeling that...
like we have this gut feeling that,
and if we analyze some of the languages,
I think that in past people have told me in so many different languages
that there is this phrase for gut feelings in so many,
like for instance, in I think Portuguese is
frio de barriga, youa, like cold in the stomach,
you get a cold.
In Spanish we call it a pre-sentimiento, like a pre-feeling, or pre-sensation or feeling.
It will be more feeling if you translate that.
As if it arrives first.
Yes, before you're able to articulate it.
So there is this storage in the entire body
that gives you, depending on the context,
it gives you a certain type of feeling.
And that's why we talk about intuition.
There is also this other aspect of how it is that food synchronizes that intuition.
It seems to synchronize that intuition among two or more people. Because if you think about it, we have this ritualistic way of serving something
when we commonly say or colloquially say,
let's go for a cup of coffee.
And often what we mean is let's go and talk about business,
the future, resolve an issue.
But we're talking about the cup of coffee
and we have to share.
And people, I think that there are some psychologists
that have ran some of these studies
in which they say that if the food
that we eat is more alike,
we are more likely to connect at least on the moment, right?
So there is this aspect and that's why we share the food.
Interesting, so is the idea that it's the actual
chemical constituents of the food
that's creating a common experience that then allows people to bond more readily?
Or is it that the specific constituents of the food are actually driving bonding per
se?
I mean, it-
Yeah.
And if we go back to if we are what we eat, then if we eat the same thing, we should be
more alike to each other, right?
That's why, you know, like in communities, you share the food.
In fact, and like if you go into certain specific communities, you pass around the food, you
pass around the drinks, you know, and it's very common to share, right?
Yeah, and certainly in romantic bonding, there are many factors, of course,
but the kind of more basic functions of food, sex,
and sleep represent the common places of bonding initially,
and conversation, of course, and values, et cetera,
not to dismiss any of those, they're essential as well,
but in terms of feelings of know, feelings of safety.
That's right.
Feelings of communing with somebody, right?
These very basic biological functions.
Yeah, and in business too, right?
Like people, there has been a study
in like behavioral economists.
They talk about how it is that business
are more likely to happen
when they are made over food or launch or things like that. There's this synchronicity in the
decision making. And here is a third dimension in this area that has not been well explored,
but I suspect that in the near future it will begin to be explored. I read a while ago a very elegant paper from Walter Cannon.
So you may want to expand on who Walter Cannon was,
but one of the founding figures of the study of physiology.
Autonomic physiology. Autonomic physiology.
Chair of physiology at Harvard in 1920s, 1930s, author of The
Wisdom of the Body. He published a paper, I believe in the 1930s. It's called Voodoo Death. Voodoo Death. And
I remember when I found that title, I was like, oh, this is something to sit down and
dissect, you know.
Yeah, good title.
Good title.
If you want somebody to read it, good title.
And he essentially the gist of it, let me see if I can do a little bit of justice,
but obviously I will chop most of the details.
But the gist of the paper is that in some observations, in some native tribes,
I believe it was in Africa, that if young people, especially young youngsters, if they were frightened by a shaman, that
they will not perform a certain thing, a certain task, right?
They enter a level of psychosis, so to speak, that could cause death, like the custom spell,
right?
And that's why it's called Vuru death.
What Kahn goes and describes is there is an activation of the vagus nerve and the peripheral
nervous system that is a hyper activation that is going through the subthreshold level
of consciousness.
And that in some of these tribes, that's what,
at least that's what he explains that is happening.
And I believe that he did some experiments in some animals.
But what he was saying is that there's a hyper tonic activation
of the peripheral nervous system when there are these spells
that are casted by a member of the tribe that is in
a higher or more superior or more influential position, that if the other member, especially
if it is paired with something, right?
Like if you say, like, if you go outside and don't listen to what I just told you and you see a black cat, those two things
match together and now you're hyper activated, right, and become superstitious about it.
But it is what Walter Cannon goes to explain is that it's a hyper activation of the peripheral
nervous system.
Obviously there's probably more details in there.
But the paper really highlights an area of exploration that we don't know about.
These are a threshold of subconsciousness of the nervous system, how it is driving us to
have superstition, to drive instinctively to go and consume certain things or behave
in certain ways, right? Yeah, so it sounds like it's paired association learning through statements, cognition, but
that's enacted through the vagus in order to control the organs of their periphery.
That's nerd speak for if we hear and believe that certain events will cause certain changes
in our physiology, they can in some instances become capable
of that.
Eat this food at this location and you'll get sick.
Eat this food at this location and you'll feel better.
It's learned association.
Ultimately, it's physiological, but it sounds like it's subject to a lot of learning effects.
As long as we're talking about the vagus, I think it's a great opportunity to just mention
that a lot of people understandably think
that the vagus nerve activation is always about calming
of the nervous system.
And indeed, the vagus is placed under the umbrella
of a parasympathetic pathway.
But I think it's very important for people to know
that both experimentally and clinically,
if the vagus nerve is stimulated,
you get exactly the opposite effect.
You get arousal effects.
This is commonly known in labs
that do physiology of different kinds.
It's in the clinical context,
people with depression are sometimes treated
with vagal nerve stimulators,
and it certainly isn't driving more sedation,
more depression of the nervous system.
It drives alertness and arousal.
So we have to, I think, make sure that we look at the vega system and describe the vagal
pathway as one that can both induce states of calm, of ease, rest and digest, as it's
sometimes called, but also states of arousal and alertness, even fear.
And so I think of the Vegas as a superhighway
of a bunch of different pathways
with lots of inputs and outputs
that's highly subject to learning.
And indeed the Vegas can slow heart rate,
you know, down through a number of things
like long exhale breathing.
Earlier we were talking about stress modulation,
something my labs worked on, extend your exhales.
That's the most basic way.
Physiological size, two inhales followed by a full exhale
to lungs empty.
These are core physiological mechanisms
known to activate the vagus and lead to calming.
But the vagus, I look at the vagus as kind of a,
including both an accelerator of sorts,
accelerator-based pathways in terms of arousal and breaks.
And probably our basal level of vagal activation
reflects sort of the RPM of our system.
How much are we calm?
Are we humming at a higher level of activity?
Such an interesting pathway,
such an interesting area of the nervous system.
And we don't really understand yet.
No, because like- Even the major branches and pathways
are just now finally beginning to be understood.
It's, we're on virgin beaches.
Yes, right now that I hear you bring up the humming,
for instance, there is a branch of the vagus
that innervates the ear, the
inner ear.
And that's why it is believed, and I think there is a little bit of evidence out there
that how it is certain music at a certain frequency will calm you down because it is
immediately like brings the, it starts to make the vegus vibrate at a certain frequency.
Yeah.
And humming has been linked to vasodilation,
which is associated with a calming effect,
whereas activation of the sympathetic arm
or the autonomic nervous system,
or the kind of, sometimes it's referred to as fight or flight,
but it's involved in other things,
causes vasoconstriction.
And if you think about it,
like in several religious practices,
there is the humming, right?
There is the singing, there is the sound.
The sound plays a big role.
In running, there is a certain frequency that calms you more and makes you run better.
Is that right?
Yeah.
There is some evidence, at least among runners, that they prefer a certain type of frequency
for the running, right?
So a certain pace of frequency for the running. Right. So certain pace of running or breathing.
And they sound, specifically the sound.
The sound of their feet.
Yeah. No, the sound of the music. Like if you play a certain music, right?
And probably the sound of their feet too, right? Like it's just that it has not been explored.
Right. It's fascinating. And you know, so much of what I think about
when I think about the nervous system
is the fine grain processing of, you know,
of color, of light or what,
but when it comes to our feelings of wellbeing,
our levels of arousal, sleep, et cetera,
it's the rather, I don't want to call them crude
because they're really sophisticated.
They evolved to be sophisticated,
but these kind of macroscopic signals
like light coming in in the morning has these long wavelength and short wavelength contrast.
That's what tells our brain it's morning.
That's right.
It's the orange, red, blue contrast.
Even if there's cloud cover, it's the difference between those two different qualities of light
that says it's morning.
And when the sun is overhead, you don't see that yellow, blue or orange, blue, red, blue
contrast, but you see it again at sunset and it informs.
So it sounds like the combination of specific chemicals in the gut tell us this is good,
pursue more of this and maybe even the place where you found it is a good place as opposed
to, and the opposite is probably also true.
Yes, like that's an entire new domain of the digestive,
the sensory system in the digestive tract
that we haven't even begin to articulate yet memory.
How do we remember like, what was that first meal?
Like in the Ratatouille movie,
from when we were children, right?
Like, it was very different.
Like, I still remember, like, some of the very simple, humble meals
that my mother would make, but it's just priceless for me, right?
Whenever I go home, it's like, I specifically,
without asking, sometimes my mother will prepare those for me.
And it's like, it just brings you back when you were that age, right?
Yeah, the memory system is tightly linked to taste and smell.
There's no question about it.
And then like the, how it is that the gut triggers those sensations or further reinforces those sensations.
We can't even begin to articulate.
And when I say articulate, because we don't even have
the language to refer to these things.
That's why at the very beginning we were talking
over there in our conversations about the axis.
And that we don't say like the nose brain axis, right?
Like we just went for what we had at that time.
And I do think that the language will continue to evolve
for us to be able to articulate more precisely,
more richly, more elegant, more, you know,
in so many different ways,
how it is that the organs communicate with each other
to make us who we are.
And in there, in one of our papers, we quoted these beautiful passages from the book,
Memoirs of a Stomach. It was written in 1853.
By a French person?
By what it says in the first page, by the minister of interior.
Because all of those who eat may read or something like that.
And then on page 21, it goes to describe the dialogue between the gut and the brain.
And it says like that, how it is that the gut communicates to the brain with a rapidity through these two sets of electrical wires
that communicate the arrivals of the day, as we may eat,
with a precision and rapidity to the brain,
so the brain will make its own feelings and impressions.
And then he said that when,
he's talking from the perspective of the stomach,
it says like when I grew more rose,
like meaning I'm not working in digestion,
then the brain also grew irritable and petulant.
Angry.
Angry.
It's so interesting to look at human experience from the directionality of gut to brain rather
than brain to gut.
That's right.
And you know, as I do from time to time, you know, pay attention to what's happening in
the landscape of wellness and mental health and physical health. A lot of what you see out there in terms of,
highly educated people who have thought very deeply
about how to navigate decision making
in lots of different domains of life
and to do it in a way that really honors
our own individual preferences and needs.
People like Martha Beck, I don't know if you've heard of her,
but she exists in the, she is triple-degree from Harvard, but has talked a lot about learning to sense one's way into
and through decisions, through intuition that is more of the body and is more of particular
brain circuits than our analytic, like, you know, pros and cons-less, you know,
because pros and cons-less and obviously important metrics
like objective metrics, like, oh, is this the right salary,
the right location, the right, you know, all the things
that matter for decision-making.
And we're trained in that in school, in the United States
and in many areas of the world as well, of course.
And that's critical, but that there's this other training,
there's this other learning of self
that can be extremely useful,
and it almost always comes back to body first,
then to cognition and decision-making.
And I feel like modern humans are trying to learn
how to run the analysis of life decision-making
through this,
I guess, more ancient axis.
So again, the intelligence of these,
what used to be called more primitive systems,
but I don't think they're primitive at all.
In talking with you today,
it's clear to me that these are highly sophisticated systems,
just as sophisticated as any four-brain pathway
involved in analyzing, say, like probability or something.
And that's why I like to highlight the example of having a nice meal
and having a nice conversation at the same time.
You know, if you go to a nice restaurant and you have a nice meal
while you're having a nice conversation, and you pay attention to it, then it brings humility to your body
to know how much your body is doing for you to be able to just express
a tiny little bit and having some sort of highly intellectual,
sophisticated conversation while you're able to put in the precise amount
of lettuce inside of your mouth
and chew it in the right way,
and like adjust it with a little bit of water
and maybe a little bit of wine,
and understand what is cleansing your palate
and like, you know, putting down the napkin
and so on and so forth
without going to the restroom every time
that you feel like going to it, right?
There is an entire sophistication of the body
just to have something like as simple
as a catch-up conversation, you know.
Do you think that our ability to sense into gut sensing more,
to really hear and respond to the signals from the gut
is something that we can learn, even as adults,
simply by paying more attention.
Yes, and I think that here's the concept that usually,
you know, when we talk about topics like meditation,
you know, is that self-care, and that self-care
is listening to your own body, right,
how it is that the body is feeling.
Like, I don't know, you know, I grew up in a, my mother will tell me like, or,
you know, family will tell you, if you feel like going to the
restroom, and to pee for a bio break, don't hold it for too
long, because it might be bad, right? Like, and I think that
just learning that part of like listening to, to the body is an
essential aspect. It's just that we're not constantly doing it
over learning about how we are moving our career forward.
Yeah, so much of what we're taught
in order to be high achieving and forward moving in life
in modern culture is about learning to override
the signals from the body.
But it seems that learning to listen to the signals from the body is
key to being a healthy human being.
Yes, and here I have an example.
Years ago, I used to run quite a bit.
And I remember that after I had run a marathon, I took a break for like a few weeks and then
I got back on the trail and I began running.
And I was like, you know, I don't need to warm up for three or four weeks up to like get
back into speed, right?
And I remember that I started to feel like that my right, the soul of my right foot was
a little bit like bothering me, like almost imperceptible.
And I was like, no, you just have to keep going.
My wife Elaine told me like, you should pay attention, take a break.
And I just kept running.
And I remember specifically that one time I went to run and say like I can put in 80
miles that I think that I was running at like 7 minutes, 7.15 a mile or something like that.
And I began running.
After a mile, I was feeling pumped, you know, two miles, three miles, I was like and then
I usually will go and do four miles and then turn around and come back.
I got a mile four and I felt crack and I could not walk anymore.
There was a hair fracture that is almost imperceptible in an x-ray but boy, that you cannot move your foot anymore. There was a hair fracture that is almost imperceptible in an x-ray but boy that you cannot
move your foot anymore. I had to limp for four miles all the way back to the car because I didn't
even have my phone and I never forgot that for next time you gotta pay attention to your body.
You know your body is simply telling you like something is a little bit off,
just don't keep pushing it.
And I specifically remember because I kept running
and I couldn't, I had to literally limp
all the way back to the car.
Well, Diego, I must say that among the many things
that you've shared with us today and taught us
about the gut and its ability to influence the brain
and the incredible things that are happening
at the level of biology and physiology of the gut.
Chief among them is the message
that we should all pay more attention
to our sensing at the level of our gut.
And nowadays we hear so much about the gut microbiome,
such that fortunately,
I think most people are starting to appreciate
that the gut microbiome is vital for all aspects of health.
And that there are things that we can do
to feed that microbiome fiber intake,
fermented food intake and so forth.
But clearly based on what you've told us today,
that even just paying a little bit more attention
to what our gut is telling us at the level of feeling good,
feeling less good, because the signs and signals are subtle,
I realize, can really help us make better decisions,
help us decide not just what foods to eat or not eat,
how much to eat or not eat,
but also how to navigate higher order decisions, if you will,
about who to spend time with, what to do, what not to do,
moving along the decision tree of life.
And along those lines,
I want to thank you for making the decision
to come here today.
I certainly am happy that we decided to do it.
It's something that's been a long time coming.
I really see you as one of the true pioneers in this area
of trying to dissect the understanding
of the gut brain axis, heal the brain through the gut,
understand and modulate our emotions
at the level of gut sensing.
And while there are other researchers in this area,
I refer to you as a pioneer
because you've really undergone this incredible trajectory
from the Amazon through nutrition science into neuroscience.
And now we're getting a little bit into psychological science
and I'm excited for what comes next.
I only ask one thing, which is that
as you make these discoveries,
that you come back and talk to us about them
so that we can learn more about
your incredible work.
So Andrew, I want to say a few things.
The first thing is that I feel deeply honored by your invitation and thank you so much for
the opportunity.
I am just simply a representative of the people that work with me and work with us.
You know, I'm just an ambassador
and they get the majority of the credit
for their dedication to help us understand
a little bit more of the body
and how it is help us to navigate the world
that we live in.
So I wanna thank you for the opportunity.
I want to thank the people that have made this possible.
Also like the people that are along the way
or the institutions that are along the way have helped fund
this endeavor, you know, my home institution at Duke.
I'm deeply grateful because my career has developed there.
And some of my mentors, Roger Little, Andrew Muir,
and the people that have helped me along the way.
And then finally, I wanna thank you and your team,
and congratulate you for the work that you do and that you have created this
window for us to come and share with the public some of the a little bit of the work that we do
perhaps some of that is obviously is based on evidence. Some portion of that is thinking about the future, but I do think that through maintaining
the dialogue with the public, that we can continue to understand the world that we live
in.
And for that, I have to thank you for having created this platform.
Well, it's a labor of love and I'm honored to be able to do it. And in no small part, because I get to sit down
and have a beautiful intimate conversations
about biology and life with you.
So thank you so much.
Thank you.
Thank you for joining me for today's discussion
about sensing with the gut and the gut brain axis
with Dr. Diego Borges.
To learn more about Dr. Borges' research
and also to see a link to his fabulous podcast
called The Gastronauts,
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