Huberman Lab - How Foods and Nutrients Control Our Moods
Episode Date: March 15, 2021This episode explains the brain-body connections that allow the specific foods we eat to control our moods and motivation. I discuss the vagus nerve and its role in dopamine and serotonin release in t...he brain. I review Omega-3 fatty acids and the key role of the gut microbiome in supporting (or hindering) our mental and emotional states. Many actionable tools are reviewed and discussed related to fasting, ketogenic and plant-based diets, probiotics, fermented foods, fish oils, artificial sweeteners, specific supplements that promote dopamine and serotonin, and some remarkable behavioral (and belief) effects. For the full show notes, visit hubermanlab.com. Thank you to our sponsors AG1 (Athletic Greens): https://athleticgreens.com/huberman LMNT: https://drinklmnt.com/huberman Supplements from Momentous https://www.livemomentous.com/huberman Timestamps (00:00:00) Introduction (00:00:31) Sponsors: AG1, LMNT (00:05:00) Emotions: Aligning Mind & Body (00:06:41) Nutrients, Neurochemicals and Mood (00:08:39) Primitive Expressions and Actions (00:12:30) The Vagus Nerve: Truth, Fiction, Function (00:15:45) “Vagus Stimulation”: A Terrible Concept (00:16:35) Polyvagal Theory (00:18:27) Vagus Senses Many Things, & Moves Our Organs (00:19:35) Sugar Sensing Without Perception of Sweetness (00:23:00) Eating-Induced Anxiety (00:27:30) We Eat Until Our Brain Perceives “Amino Acid Threshold” (00:29:45) Reward Prediction Error: Buildup, Letdown and Wanting More (00:32:01) L-Tyrosine, Dopamine, Motivation, Mood, & Movement (00:34:04) Supplementing L-Tyrosine, Drugs of Abuse, Wellbutrin (00:38:29) Serotonin: Gut, Brain, Satiety and Prozac (00:43:38) Eating to Promote Dopamine (Daytime) & Serotonin (Night Time) (00:44:30) Supplementing Serotonin: Sleep, & Caution About Sleep Disruptions (00:46:40) Examine.com An Amazing Cost-Free Resource with Links to Science Papers (00:48:05) Mucuna Pruriens: The Dopamine Bean with a Serotonin Outer Shell (00:51:00) Emotional Context and Book Recommendation: “How Emotions Are Made” (00:54:55) Exercise: Powerful Mood Enhancer, But Lacks Specificity (00:56:45) Omega-3: Omega-6 Ratios, Fish Oil and Alleviating Depression (01:01:00) Fish Oil as Antidepressant (01:02:40) EPAs May Improve Mood via Heart Rate Variability: Gut-Heart-Brain (01:07:24) Alternatives to Fish Oil to Obtain Sufficient Omega-3/EPAs (01:09:05) L-Carnitine for Mood, Sperm and Ovary Quality, Autism, Fibromyalgia, Migraine (01:16:29) Gut-Microbiome: Myths, Truths & the Tubes Within Us (01:21:55) Probiotics, Brain Fog, Autism, Fermentation (01:25:20) Artificial Sweeteners & the Gut Microbiome: NOT All Bad; It Depends! (01:28:00) Ketogenic, Vegan, & Processed Food Effects, Individual Differences (01:33:20) Fasting-Based Depletion of Our Microbiome (01:35:20) How Mindset Effects Our Responses to Foods: Amazing (Ghrelin) Effects! (01:38:30) How Mindset Controls Our Metabolism (01:41:03) Closing Comments, Thanks, Support & Resources Title Card Photo Credit: Mike Blabac Disclaimer
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Welcome to the Huberman Lab podcast where we discuss science and science-based tools for everyday life.
My name is Andrew Huberman and I'm a professor of neurobiology and ophthalmology at Stanford School of Medicine.
This podcast is separate from my teaching and research roles at Stanford.
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Today we're talking all about emotions.
Emotions are central to our entire experience of life.
Whether or not we're happy or sad or depressed or angry is our life experience.
And yet I think with all the importance that we've placed on emotions, very few people actually understand how emotions arise in our brain and body.
And I mentioned brain and body because
as you'll see today, emotions really capture the brain body relationship. We cannot say
that emotions arise just from what happens in our head. It also involves events, biological
events, chemical events within our body.
The other thing about emotions is that there's no real agreement as to what's a good emotion
or a bad emotion
Today we're going to talk about the biology of the chemicals and pathways that give rise to emotions and I'm going to equip you with
several if not many tools that will allow you to regulate and change and steer your emotions should you want but not using the typical advice
You know everyone's probably heard of this thing. oh, you know, if you're feeling depressed, just smile,
you know, when you get it's impossible to be depressed while smiling.
Look, if that were true, we wouldn't have any depressed people,
because depressed people don't want to be depressed.
And it is not the case that simply smiling
will reverse depression or sadness,
and it's simply not the case that smiling can inhibit sadness.
It just doesn't work that way. However, it is the
case that certain things that are happening in our body influence how our brain functions and the
chemicals that are released. And today we're going to talk a lot about how the brain and body
interact to create these things called emotions in the context of food and nutrition. And the reason
we're doing that is not because
I am beating the drum about particular diet regimens
or anything, in fact, I'm not gonna do any of that.
What I'm going to do is I'm gonna review
some of the most important scientific data
that point to how ingesting certain nutrients,
both macronutrients like proteins, fats,
and carbohydrates, as well as micronutrients,
can impact the chemicals in our brain that
give rise to the feelings of being happy, or sad, or sleepy, or alert when you want to
be sleepy, or sleepy when you want to be alert.
So this is sure to be a broad discussion, and yet we're going to get very specific about
what emotions are, how they arise in the body.
Tools that one can use in order to better control their
emotions, tools that people can use to believe it or not feel happier or feel calmer.
And that's because in the last 20 years or so, there's been an explosion of scientific
studies exploring how the brain and body interact to support certain neurochemicals that
give us these feelings of being alert and happy
or depressed or certain that our life is going to be terrible or certain that our life
is going to be great.
So as mysterious as all that might sound and confusing as all that might sound, we're
going to make it very clear today and you're going to come away from this conversation
with a lot of tools that you can act on immediately.
And those tools are grounded in scientific data.
We are going to provide links to several of the studies.
And I'm going to mention several of those studies
as we go along.
But overall, the goal today is for you
to understand how moods and emotions arise
and the different pathways in your brain
embody that allow them to happen and how you can use those
pathways to change those emotions and the tools that you can rely on
in very specific ways to shift from being, say, slightly depressed to feeling happier.
There are actually our ways to do that, or from feeling too alert and anxious to feeling calmer.
And these are tools that are distinct from the tools I've talked about in previous episodes.
The discussion around emotions has a long and rich history
going back to Darwin and even long before Darwin.
This is a conversation that philosophers and scientists
have been having for hundreds, if not thousands of years.
The idea that Darwin put forth and that was really attractive
for about the last 100 years was that emotions are universal
and that some of the facial expressions around emotion are universal.
And other people have, you know, capitalized on that idea.
And to some extent, it's true. I mean, I think that the two most robust examples of that would be when we see something,
or we smell something, or we taste something that we like, there does tend to be a postural
leaning in. We tend to inhale air at that time. We tend to bring in more of
whatever chemical substance is there. So we tend to do these, and you know, and
kind of lean in closer to things that are attractive to us. And when we see and
experience things that we don't like, sometimes it's a mild aversion. We just
kind of lean back or look away.
Other times it's an intensive version of disgust
and we tend to cringe our face.
We tend to avoid inhaling any of the chemicals.
This probably has roots in ancient biological mechanisms
that are to prevent us from ingesting things
that are bad for us, chemical compounds
and taste that might be poisonous.
So much of the foundation of any discussion about emotion has to center around this kind
of push pull of attraction to things or aversion from things.
Now that's a very basic way of thinking about emotions, but if you think about it, it
works for a lot of different circumstances, and in the brain, everywhere from the deep
circuits of the brain to the more kind of what we call higher order, or evolved centers of the brain, we have this push pull thing.
We're either in previous episode I talked about go, the circuits that allow you to emphasize
action and then no go circuits, the circuits in the basal ganglia that allow you to deemphasize
action and prevent action.
We talked about how that's a push pull.
So a version and attraction is a push pull too. Delight or happiness or excitement are
attractions to certain things and ideas, songs, people, places, foods. A
version is a leaning out. It's a disgust. It's an avoidance. And so we can break
down the discussion about emotions into these simpler versions of themselves.
But at the core of that, of attraction or aversion is an important theme that you might realize already,
but most people tend to overlook, which is that there's an action there.
You're either moving forward or you're moving away from something.
And anytime you're talking about action in the nervous system,
you're talking about motor behaviors, you're talking about action in the nervous system, you're talking about motor behaviors.
You're talking about literally the contraction
of muscles to move you toward or away from things.
And anytime you're talking about nerve to muscle and action,
you're talking about the brain and the body.
Because the brain can't move itself.
The brain has a body so that the organism can move. And the body has a body so that the organism can move and the body has a brain so that
the organism you can move toward or away from things that you deem to be good or bad
for you. Now, some of these things that we're attracted to and some of them that we avoid
are what we call innate or hardwired. You know, when we taste bitter compounds, I'm not
saying about bitter, like you like a little bit of bitters in your drink or something like that, but really bitter compounds. We tend to
avoid those because they're associated with poisons. When we taste things that
are sweet or that are savory, we tend to
pursue more of those. We tend to lean toward those, so to speak, and we tend to
not avoid them. So there are circuits in the brain for a version and for attraction
toward things, and the body is governing a lot of that. And so immediately in this conversation,
I want to raise an important point, which is about a nerve pathway that many, many people have heard of,
that gets discussed all the time and that is one of the most kind of oversold for the wrong reasons and undersold, unfortunately, for its real power,
which is the vagus nerve.
So the vagus nerve is one, not the only, but one way in which our brain and body are connected
and regulates our emotional states.
Now many of you have probably heard about polyvegal theory.
I'm going to talk about this today.
Polyvegal theory was popularized
by Stephen Porcus. And it's an interesting theory. Certain aspects of it, frankly, hold up to the
science. Some of it doesn't. And I'm going to discuss all of that today. A lot of the Vegas and
the excitement about the Vegas V.A.G. U.S. is because it somehow got into the mind of the public that the Vegas is involved in calming us down.
So what is the Vegas nerve? Okay.
We're going to make this really simple, particular for those that are just listening.
You can just imagine this for those either watching.
I'll point to the various areas, but basically,
Vegas is the 10th cranial nerve, which basically means that the neurons, the
kind of the control center of each of those neurons in the vagus, lives just kind of near
the neck, right?
And a branch of the vagus goes into the brain.
They send a little wire into the brain.
The other branch goes into the periphery, but not just the gut.
It goes into the stomach, the intestines, the heart, the lungs, and the immune system.
So this vagus nerve is incredible because it's taking information from the body and it
has two directions.
The first is what we call sensory.
So it's sensing things that are happening in the gut, in the lungs.
Everything, for example, in the lungs when our lungs are distended, the vagus nerve senses
that and sends that information up into the brain.
It also can sense things in the gut, like how distended or empty your stomach happens to
be.
It can sense heart rate.
It can sense your immune system, whether or not you have bacteria or things invading
you in your body.
So it sends that information up to the brain.
So it's a two-way street and sensory information is going up to the brain.
That's all vagus.
So it's like a super highway sensory information going one way.
And in the other direction is motor control.
So the Vegas is not just for sensing things, it's actually for controlling things.
It's got a sensory pathway and a motor pathway.
So that's the first thing I think everyone should know about the Vegas.
In fact, it's so important that I feel like this is as important as people knowing that
walking involves flexors and extensors.
And if you don't think that's important, it's as important as walking, frankly, because
the vagus is the way in which you can govern the brain body connection and in which you
can steer various aspects of your mood and well-being.
But most people just don't understand how to use it.
So first, you got to understand what it is.
So you've got sensory information coming from all these different organs of the body up
to the brain.
You've got motor information going from the brain back to the body.
And so you've got this super highway within you.
Now what actually regulates the vagus?
Oftentimes you'll hear things like, oh, you know, this particular behavior, you know,
rubbing it, your face at a particular location or breathing in a particular way or, you know, rubbing your face at a particular location or breathing in a particular way or
you know, a warm bath or something stimulates the vagus. Well right now
I want everyone to know that quote-unquote stimulating the vagus, broadly speaking, is a terrible way to think about the vagus.
Because did you know what?
If you have a contaminant inside your body, the vagus senses that and
contaminant inside your body. The vagus senses that and projects that information to your brain, and you start to generate a fever. You start to try and kill that contaminant in your body.
So I don't know that you want to stimulate the vagus just as a general theme. Today we're going
to get specific about how you can activate particular circuits, certain pathways from certain
organs to the brain in order to feel better or relieve certain conditions, but you certainly don't want to just stimulate the vagus. Now, excitement about the vagus in part is because of what
quite honestly was a fairly pioneering theory about the vagus, which is this polyvegal theory.
So polyvegal, the word poly means many, is cool because it acknowledges
that the Vegas has a lot of different branches. It's not just one thing. And so I really like
that. I like the naming, Polyvago. The idea that Portis put forward was that there's
a door sole Vegas, which is kind of runs the back of the spinal cord, which is involved
in alertness and activation and kind of fighter flight type stuff, and that there's a ventral pathway, and that that's involved in more
kind of empathic behaviors.
That is not quite in agreement with the modern anatomy, but you know, he was doing the best
with what he had at the time.
So, okay.
The problem I have with the polyvagal theory is the way that it's discussed. People often say, oh, you know, if your dorsal vagus is too active, then you tend to be someone
who's a little too keyed up.
And people who are kind of in a state of freeze or kind of flaccid and kind of, you know,
like just not really active and they're just lethargic, well, then that pathway is hypoactive.
It should be more active. So there are a lot of theories about how psychology maps onto the Well then that pathway is hypoactive, it should be more active.
So there are a lot of theories
about how psychology maps onto the Vegas
that as far as I know,
don't map to any real physiology.
Now, the other problem with this kind of,
the way that the polyvagal theory is discussed,
probably not by the real experts,
but by a lot of people is that people started
to diagnose different psychological
and physical manifestations through the Vegas.
They would say things like,
oh, you know, this person is hyper flexible at the joints
and therefore their dorsal Vegas
isn't active enough or something like that.
And it's really kind of gone way outside the lane lines.
So today we're gonna clean up a lot of that.
Let's make it really simple about how the Vegas
actually works, at least as we understand it today in 2021. First of all, as I mentioned, you have sensory information,
the same way that you detect light with your eyes or you hear sounds with your ears.
You have sensors in your gut that sense how full or empty your gut is. It can also sense
how acidic your gut is. It can sense various things within your gut.
Your heart is doing the same.
It's informing the brain how fast your heart is beating, how full your lungs are has been
communicated, and then the status of your immune system.
So the way to think about the Vegas is the same way I would think about the eyes.
The eyes are looking at colors, they're looking at motion, they're looking how bright it
is.
And each one of those things, those features, is telling the brain something different so the brain can decide when to be
awake or asleep, whether or not it's looking at somebody attractive or unattractive. The vagus
nerve is also analyzing many features within the body and informing the brain of how to feel about
that and what to do. So a really good example that I think is an exciting one
is as it relates to sugar.
So we all know that sweet things generally taste good.
I'm not particularly a fan of very sweet things.
You know, I'd much rather have cheese or pizza
or hamburger or steak.
I like savory fatty foods, but I do like sweet foods.
And most people find sweet foods to be attractive.
They want them.
Or they might not be able to regulate their behavior
around them, but they want them.
And what's really interesting is that for hundreds of years,
people have thought that that's because of the way
that sweet foods taste.
So that makes sense, right?
You eat something and taste sweet. You want more of it.
Well, it turns out that it's much more interesting than that when you eat something sweet.
Within your stomach, you have cells, neurons that sense the presence of sugary foods, independent of their taste, and signal to the brain. So those sensors, those neurons,
send information up the vagus to your brain,
goes through a series of stations,
and then you release dopamine, this molecule,
that makes you want more of whatever it is that you just ingested.
In fact, this pathway is so powerful
that they've done experiments where they completely numb
all the taste and feeling in somebody's mouth.
They're blindfolded so they don't know what they're eating and they're eating a food that's
either sugary or not sugary.
And what they find is that even though people can't taste the sugary food, they crave more
of the food that contains sugar because of the sensors in the gut that sense sugar.
So to put this differently, you actually have sensors within your body that
make you crave sugar independent of the sweet taste of those things. Now that's incredible. And what
it does and what it tells us is that we have circuits in our body that are driving us towards certain
behaviors and making us feel good, even though we can't perceive them. Now for those of you that are really interested in gut intuition and kind of gut feelings,
this is a gut feeling, except this is a chemical gut feeling.
This is a particular set of neurons detecting that something in your body has a particular
feature, in this case the presence of sugars, and sending information to the brain to essentially
to control your behavior.
And I find this remarkable because what it means is that what we call attractive isn't always
coming from our thoughts about that or our feelings are even our perception.
We are drawn to particular foods and we're drawn to perhaps also to particular people, places
and other things because of information that's coming
from our body.
And we're going to talk about what one can do with this information.
I know many people are thoughtful or concerned about sugars these days thinking, you know,
we all ingest too much sugar, there's sugar snuck into all the things we eat.
And indeed, that's true.
I mean, this should completely reframe the way that we think about the sort of so-called
hidden sugars in foods
What this means is that even if a food is very savory like a piece of pizza or a or a piece of bread or
Even like a salad dressing if their sugar snuck into that and you can't taste it
You will still crave more of that thing without knowing that you crave it because it has sugar in other words
You might find yourself wanting certain foods and not knowing that you crave it because it has sugar. In other words, you might find yourself wanting certain
foods and not knowing why you want those foods.
So I find this to be a fascinating aspect of our biology.
And yes, it relates to mood and emotion.
And we'll talk about how that is in a moment.
So let's just back up a bit and ask the question,
why do we eat certain things?
And why do certain foods make us feel good?
And other foods actually make us feel anxious.
I think some people may be familiar with this,
other people might not.
But most people don't realize that as you approach eating,
there's an anxiety associated with that.
It's an alertness.
Remember in the previous discussions,
or even if you don't, and you haven't seen those,
all of your moods
and feelings of well-being are anchored on this continuum
of alertness versus calmness.
And we hear so often about rest and digest,
that oh, after we eat, we feel really nice and full,
hopefully comfortably full and not too full.
And we're relaxing and we feel satiated
to associate with serotonin, this molecule of satiation, that's all true.
But what most people don't know is that there's an area of the hypothalamus, so deep in the
brain, kind of in the middle, deep portion of the brain, called the lateral hypothalamus.
And the lateral hypothalamus is really interesting because it controls feeding, but it inhibits
feeding.
It stops us from feeding. And there's another area
in the brain. If you want names, I'll give them to you. If you don't want names, just
ignore them, delete them from your memory and awareness called the locus serulius. Now
the locus serulius sits back further in the brain stem and it releases noripinephrine,
which is essentially adrenaline. It makes us feel alert. Now locus serulius has a lot
of different functions in the brain, but when we are going
to eat, let's say we walk into a restaurant, we sit down, or we're preparing a meal,
locus ceruleus is known to release noradrenaline in the brain.
It's creating a kind of alertness.
This has ancient utility, but it's creating this alertness, and for many people they experience
that as they approach food as stress as anxiety.
But what's interesting is that as we approach food, locus serulias is releasing all these
molecules that make us feel more anxious and alert.
Sometimes it's felt as excitement and that's probably to do with how we feel about food
generally.
Are we happy with our relationship to food?
Are we trying to restrict our relationship to food?
Are people coming over for dinner? All that will play in, of course. But there's a certain
stress and anxiety on approach to food. And as we approach food and we feel that anxiety,
locuseruleus activates the lateral hypothalamus in a way that inhibits feeding that makes us not want to eat.
So a lot of people who have kind of pre meal anxiety or anxiety around food and they can't
seem to just calm down and have a good meal to access that later rest and digest.
A lot of that is because of this heightened stress upon approach to food.
And a lot of the tools that are out there, both for eating disorders and for just kind
of the general public who isn't suffering from eating disorders things like
mindfulness
Around meals, you know, they always tell you you know, you should never eat when stressed
I'm sorry, but my life is not organizing a way that I can't do that. I would never eat right because I eat when I'm awake
And I'm I don't know if I'm stressed, but I I don't think I am but I tend to you know run around a lot during the day
I don't generally take time to do two or three deep breaths before I eat.
I generally will just keep, it will eat.
That can be healthier, unhealthy depending on the quality of your digestion.
I think using digestion as a guide is good.
But a lot of people aren't aware that this interaction between locustsuruleus and lateral
hypothalamus is a basic mechanism where we are supposed to get a little bit alert and anxious around meal time.
And then as we eat, the mechanisms for calming and satiation are supposed to kick in.
And those mechanisms involve, as I mentioned earlier, two things.
One is how things taste. Digestion starts in the mouth. Of course, we're taste our food. Everyone tells us we should
chew our food more. Yes, that can improve digestion. We're not supposed to drink too many fluids as we
eat. That's true too. But a lot of how we feel while we eat and after we eat is because of this
vagus sensing of what's in our gut. It's sending information all the time. Is there sugar?
Are there fats? Are there contaminants? There are a lot of information, these so-called parallel
pathways that are going up into our brain, that regulate whether or not we want to eat more of
something or not. And there are accelerators, things that make us want to eat more, like sugar,
and fats, because those are nutrient dense and they helps generally at
least in the short term support the survival of animals but also amino acids.
And this is very important. There are a lot of data but much of what comes from
the data on what people eat and how much they eat is from a subconscious detection of how many amino acids
and what the array, meaning the constellation of amino acids is in a given food.
And it's fair to say that some total of these studies point in a direction where people
will basically eat, not until their stomach is full, but until the brain perceives
that they have adequate intake of amino acids.
Now, this is a conversation that comes up
in the context of the meat only, the keto,
the kind of zone diet, the Mediterranean diet,
the vegan diet, I'm largely going to ignore
the kind of strict camps today.
I will talk a little bit about it because I think each one of them actually taps into
something important about this brain body relationship that the other ones don't.
But I don't want to get into a discussion about the ethics of different foods of animal
based or non animal based because that's not the topic today.
It's really about nutrient sensing and amino acid sensing.
So we generally will eat until our gut tells our brain that we have adequate amounts of
these amino acids.
Amino acids, of course, are important because they are the building blocks of sure muscle
and the other things in our body that need repair.
But what most people don't realize is that amino acids are what the neurochemicals in
the brain are made from.
Now this is vitally important, okay? So we've heard dopamine is a
molecule that makes you feel good. Actually dopamine is a molecule that makes
you feel good. It's released within the brain and it does feel very good when
you have dopamine release. Dopamine release is caused by surprise, excitement,
events that you're
looking forward to and that turn out well. It is inhibited by events you're looking forward
to that don't work out. When someone says they're going to call that you're really, really
excited to talk to and then they don't. Or you thought a movie was going to be really
great and it's not. Or you expect a meal to be really delicious and it's kind of eh.
And we actually, there's a name for that. It's called reward prediction error.
So, and you can actually use this in the context of meals and plans
in a way that's very useful with yourself and people you know.
Essentially, if you expect something to be really terrific,
it really does place a higher expectation at the chemical level.
So, if you don't get as much dopamine as you're expecting from something, so you hear about
a really great restaurant or a place that has a really, in my case, I wouldn't call it an
addiction, I would call it more of an affliction for croissants.
The best vegetable, of course, is the croissant.
And I get really excited about the fact that someone will tell me, oh, there's this place
and they have incredible croissants.
You got to go there.
So I'm really excited and I'll go
and just them telling me that it's gonna be really terrific,
raises an expectation, a dopamine expectation,
and unless those croissants are amazing,
chances are I'm going to experience them as less good,
less satisfying, I will truly release less dopamine, then I would have they
just said, oh yeah, I think that there are croissants down the street, or if I just tried
one at random.
And that's because of this reward prediction error.
Your expectation of something releases dopamine and the actual event releases dopamine.
And if the event related dopamine does not exceed the expectation or at least match it,
there's a much higher tendency that you won't pursue that thing again. So dopamine is really powerful
and it's not just the molecule of reward, it is the molecule of desire, it's the molecule of wanting,
not just the molecule of having. And a book, since people often ask for book recommendations,
I don't know the author personally, but I love the book.
It's called The Molecule of More. It's a terrific book. I wish I had written it frankly.
But if you want to learn more about dopamine, reward prediction error, and how dopamine regulates various aspects of your emotional and motivational life, it's a terrific read.
Dopamine is what's going to lead us to want to eat more of something or to not want more
of something because dopamine really is about craving.
It's about motivation and it's about desire.
And as I mentioned, these amino acid sensors in our gut are detecting how many amino acids
but they're also detecting which amino acids.
And there's a particular amino acid called L-tyrosine, which comes from food.
You can look up online which foods contain L-tyrosine. It is in meats, it is in nuts, it is also in some plant-based foods.
L-tyrosine is the precursor to a couple other molecules like L-dopa, etc. that make dopamine.
And so there's a misconception out there that most of the serotonin is in our gut and most
of the dopamine is in our gut and therefore our mood is in our gut.
That's not quite the way it works.
Okay?
We'll talk about serotonin in a moment, but dopamine is synthesized from the amino acids
that you eat.
However, the dopamine neurons that give rise to these feelings of good or wanting
more or desire and motivation, those reside in the brain. So we don't want to get too confused.
We want to respect and honor the power of the gut and this vagal pathway, but it's really
neurons within your brain that drive the pursuit and decision making. So what does this mean?
Well, some people make too little dopamine. Some people
make so little dopamine that they need prescription dopamine. They need aldopa. People with Parkinson's
take aldopa and other compounds to increase dopamine because Parkinson's is associated with
deficits in movement. It starts as a tremor. Actually starts as some other things that are
interesting. We'll talk about in a moment. But Parkinson's is a depression.
It's a blunting of motivation and mood and affect.
And it's a tremor.
And then eventually, in severe conditions, it's challenges in speaking and walking.
So that some famous examples would be, you know, Muhammad Ali, Michael J. Fox, the great
boxing trainer, Freddie Roach, like these people have Parkinson's and they at
least later in their life had challenges speaking.
Now it's not just fighters that develop Parkinson's.
As far as I know, Michael J. Fox wasn't a fighter.
People can develop Parkinson's and Parkinson's is a depletion of dopamine neurons in the
brain.
And it's not just movement challenges, it's challenges with mood.
Now hopefully most of you, all of you, don't have Parkinson's, but it's clear that dietary
altyrosine supports the healthy production of things like dopamine, and as well as other
factors within the brain. Now, some people immediately ask, well, should I supplement
altyrosine? So let's just talk about that because that's going to come up. Full disclosure, I sometimes take L-tyrosine.
I'm not taking it right now, but I take it only occasionally. You can buy this in
capsule form. It does increase kind of mood and elevation and alertness. It is
over the counter. You have to check with your doctor. I'm not responsible for your
healthcare and I'm not a doctor, whether or not it's safe for you. People with pre-existing hyper-dopamin urgent conditions
like mania should probably not take L-tyrosine.
The other thing about taking L-tyrosine is there is a crash.
It's not a massive crash if you take it
at appropriate doses and it's right for you,
but it can produce a crash and a lethargy
and a kind of brain fog after the next day or so.
And so L-tyrosine, however, can be ingested through foods or through supplementation
to increased dopamine levels.
That's well known.
Taking chronically, however, it can disrupt those dopamine pathways.
Now, there are other drugs that will increase L-tyrosine and dopamine as well, but those
are severe enough that they generally tend to have addictive properties.
So things like methamphetamine, things those are severe enough that they generally tend to have addictive properties.
So things like methamphetamine, things like cocaine are terrible because they really ramp
up the dopamine system so much that people really can't achieve dopamine release through
any other mechanisms.
But food and the ingestion of altyrosine has a profound effect on our levels of dopamine.
It takes a little while, but that really will impact level of mood. Certain
antidepressants fall into the category of dopaminergic antidepressants. One of
the most famous ones, of course, is well-butron. Well-butron was developed
because a lot of the other antidepressants tend to make people feel kind of
lethargic or they had side-effect profiles that people didn't like. So they
developed this thing that the generic name
is different, but it's generally called well butren. Well butren activates dopamine and
epinephrine, which is a substrate of dopamine. And both of those are involved in motivation
and alertness and effort. So you might say, wow, this sounds like a great drug. However,
this drug, the side effect profile tends to be the things that are associated with elevated
mood and alertness. So this isn't like taking some of the entire scene. This isn't like eating some tyrosine rich foods.
This is really a much greater release of dopamine and epinephrine and it increases things like anxiety.
Sweating, the pupils dilate. It has certain effects on in particular people with epilepsy.
It's been used somewhat successfully for smoking cessation, but again, it's not for everybody.
And I'm not here to encourage the use of these things.
I'm just describing the biology
and the rationale for why these drugs were developed.
So let's back up a second.
Let's just kind of take stock of where we're at.
We have a brain body connection.
There are many of them, but one of the main ones
is the vagus nerve.
The vagus collects information about a lot of things, breathing heart rate, stuff that's
happening in the gut, et cetera, and gut, by the way, includes the stomach and the intestines,
sends that information up to the brain.
The brain is using that information to decide one of two things, move towards something or
move away.
It can also pause, but essentially pausing is not moving toward.
So that's the dopamine
pathway and foods rich in altyrosine generally give us an elevated mood and make us want
to do more of whatever it is that we happen to be doing as well as other things. Motivation
generalizes to other things. It's not unique to just ingesting foods, but foods that give
us a big pulse of dopamine will make us crave more of that food. It will make us crave more of the activity
that led to the ingestion of that food.
And as I mentioned earlier, a lot of that is happening
at a subconscious level that you're not even aware of.
And this is why I think the concern about hidden sugars
and over-ingestion of sugars is serious
because it's not just that the sugars are impacting
our blood glucose in
negative ways, although often it is. It's not just the obesity crisis that's
happening. It's also the fact that it's disrupting our dopamine systems. Now
that doesn't mean all sugar is bad. Some people have a quite healthy
relationship to sugar, but I think most people are just not aware that sugar
isn't just operating at the level of taste. It's operating at the level of
neurochemicals and it's doing it subconsciously.
I'd like to talk about some of the other pathways between brain and body that regulate our
moods and emotions, but also are actionable.
The other neuromodulator that's really interesting in the context of the Vegas is serotonin.
Serotonin, just to remind you, is a neuromodulator. Therefore, it creates a bias
in which neural circuits, which neurons in the brain and body are going to be active, and
it makes it less likely that other ones are going to be active. I think it's fair to
say, without ever having measured it, that my bulldog Costello must just, his brain and
body must be swimming in serotonin because he's very calm and
he eats a lot, but he generally feels pretty sated.
He's kind of an animal that's obsessed with comforts.
He's a bit of a hedonist.
And serotonin, when it's elevated, tends to make us feel really comfortable and kind of
blissed out wherever we are.
And that contrast with dopamine and epinephrine, which mainly put us in pursuit of things.
Motivation is pursuit.
Serotonin is more about feeling really comfy where we are.
The conversation around the brain body relationship and mood in serotonin for many years was,
well, you eat a big meal, the gut is distended, you've got all the nutrients you need, you
rest and digest, and serotonin is released.
That's sort of true, but there's a lot more going on and a lot more that's interesting
and actionable that's going on.
First of all, some of you, but perhaps not all, I've heard that more than 90% of the serotonin
that we make is in our gut.
And indeed, we have a lot of serotonin in our gut.
We have neurons in our gut.
It makes serotonin. We have neurons in our gut. It
makes serotonin. We have neurons in our brain. They make serotonin. But here's the deal.
Most of the serotonin that impacts our mood and our mental state is not in our gut. Most
of it is in the neurons of the brain in an area called the Raffae nucleus of the brain.
There are a few other locations too. And those are the neurons that control whether or not we feel satiated or not, whether or
not we feel happy and calm.
You can't have a discussion about serotonin without having a discussion about antidepressants
because during the late 80s and early 90s there was this explosion in the number of prescription
drugs that were released, things like first one and most famous one is prozac, zooloft, and umpaxil, a number of other ones that are so-called SSRI, selective serotonin
reuptake inhibitors.
That's a long acronym, but basically those drugs work by preventing the gobbling up of serotonin
or reuptake of serotonin into neurons after it's been released, which leads to more serotonin or reuptake of serotonin into neurons after it's been released, which leads to more serotonin overall,
which means to elevate serotonin. And indeed those drugs were and can be very useful for certain people to feel better
in cases of depression and some other clinical disorders as well. So I really don't want to
dismiss them as useless or dangerous for everybody. They can be quite useful for many people.
Not everyone responds well to them, as I'm sure you've all heard, and their side-effect profile
has effects like blunting affect. It can make people feel kind of flat, kind of meh. It can
reduce appetite for food, it can reduce appetite for sex, it can do all sorts of things,
reduce appetite for food, it can reduce appetite for sex, it can do all sorts of things,
or it can work really well, sometimes it's a dose-related issue, etc.
Serotonin is fascinating, however, because
how well those neurons in the Raffa work is impacted by some events within the gut, although
you might be surprised to find out what those events are.
So let's go a little bit deeper into the gut, and again the gut includes the stomach and then the small intestine and the large intestine and ask like what is going
on with serotonin in the gut? How is it impacting serotonin in the brain? And let's think about this
in the context of how some of us might want to increase or decrease our serotonin levels. So as far as I know, there aren't any really good
at home blood tests for things like serotonin and dopamine.
There's some commercial products out there,
but to me, just to me, I'm not particularly impressed.
You know, it's not the same as getting your hormones
levels measured or your metabolic factors measured.
That can be done and can be done rigorously.
There are tests out there.
There are even some, believe it or not,
there's some questionnaires,
and I think actually last year
it made some of the bigger newspapers.
Are you more of a dopamine or a serotonin?
Are you a this or a that?
I find that stuff to be a little silly,
although I do appreciate and like the fact
that people are thinking about
and talking about neuromodulators,
there aren't really great ways to
measure these things outside the clinic. There's some great clinical tools that you can get inside
of a hospital or from a proper endocrinologist or neurologist, but no great at-home tools. So maybe
that's a call to arms for some of you entrepreneurial folks out there to create these tests, accurate tests,
please, that could be done at home. But you know, some people feel like they're too anxious or they're always in a motivated state and they're trying to adjust
their serotonin. Many people adjust their serotonin by just eating more food. And carbohydrate
rich foods will increase serotonin. I've talked about this on a previous podcast, but I personally,
am a big fan at least for me, as I usually fast and exercise in the early part of the day.
I eat a relatively high protein moderate fat zero carb or low carb meal at lunch and in the afternoon to stay alert
because those foods tend to favor dopamine production, acetylcholine production, epinephrine production and alertness.
My mood is generally pretty good most of the time.
And then as evening comes around
and I'm concerned about sleep and a good night's sleep,
not concerned in an anxious way,
but I want to get a good night's sleep,
I will ingest foods that promote serotonin release
because they contain a lot of trip to fan.
So if I do eat meat, it would be like a white meat turkey meat.
I don't tend to, I've never liked turkey.
I don't mind the animal,
but I don't like ing meat turkey meat. I don't tend to, I've never liked turkey. I don't mind the animal, but I don't like ingesting the meat.
But starchy carbohydrates will increase serotonin.
Some people also will take serotonin.
They, you can now buy five HTP supplements.
This is a little bit tricky.
Five HTP supplements can, of course,
increase five HTP.
It is five HTP or serotonin, but that sometimes can create problems in
endogenous or self-made production of serotonin. So I'm never a fan of taking things very close to
the chemical you're trying to increase for very long periods of time. Maybe for occasional use,
I have the problem that if I take serotonin supplements, 5HGP, I fall asleep. The sleep I have the problem that if I take serotonin supplements, 5HTP, I fall asleep. The sleep I have is very intense
and I wake up three or four hours later
and we know based on sleep studies
with good measurements in the lab
that serotonin release tends to be in the later part
of the night and so by taking it early in the night,
it really can disrupt the pattern of sleep
in the depth of sleep.
Nonetheless, some people are interested in taking serotonin
to get some of the more blisted out effects.
You can achieve that with foods, as I mentioned, that are carbohydrate-rich.
So as you're seeing, this isn't really a discussion about nutrition per se.
This is a discussion about food, which contains amino acids, amino acids being the precursors
to neuromodulators, and neuromodulators having a profound effect on your overall state of
alertness or calmness, happiness, sadness, and well-being.
So there are a number of things that one can take,
as I mentioned, one of them being 5-HTP itself.
Now, I'm not recommending people take anything,
but if you're interested in what this does,
and you want to explore this, of course,
you'd want permission from your doctor,
you can go to this free website.
I love this resource.
They don't pay me to say that.
I just love this resource.
I followed it for a long time called examin.com.
Thank you folks at examin.com for putting this free resource out on the web that has links
through what they call the human effect matrix.
So it's links to all the PubMed studies for particular effects of particular compounds
that one can buy and ingest.
Incredible, as well as important health warnings.
So I'm not gonna read through everything,
but if you were to go to examine.com, as I have now,
and you'd put in 5HTP,
they're only looking at things that have strong evidence,
PubMed articles, articles are in the PubMed archive.
So for instance, I didn't know this,
but 5HTP produces a notable decrease in appetite, three studies.
And this appetite suppression makes sense, of course, because we ingest foods to get serotonin.
And if we have enough serotonin, then there's no reason to ingest more foods.
It tends to have a blunting of appetite.
It probably does that also through other mechanisms.
So I'm not saying you should do this, but if someone's trying to blunt their appetite, it could be an interesting route, although I don't recommend
chronic use. Not surprisingly, it has a decrease in body weight, as a consequence, an increase
in cortisol. So that's kind of important to note that when you typically in biology, if you pull
on one string really hard, another one moves, it's a little bit like a puppet and there's more than
one string on the puppet.
So it does seem to increase cortisol though.
They report as a minor effect.
Again, links to all those studies are there, which is why I'm not listing them out in our
caption notes.
You can go and get them at examin.com, put in serotonin and you'll find that.
So I find it fascinating that nowadays, there are things that are somewhere between doing nothing, getting
serotonin from triptophan and foods and prescription drugs.
There's this other category of supplements that are really interesting for modulating these
chemicals in the body.
And I should mention before I move on, because I mentioned L. Tyrosine, I neglected to mention
earlier in our discussion about dopamine.
If you're interested in the dopamine pathway, go to examine.com, put in macuna prurins, it's MUCUNA, P separate word,
PRU, R-I-E-N-S. It is a velvet bean that grows from vines and is very itchy to touch due
to serotonin on its surface.
Amazing. This bean has serotonin on its surface.
And indeed, serotonin, if you were to put it on your skin, would cause some irritation
of the skin. Amazing. Inside the bean is aldopa.
McRoon appearance is not just something that promotes dopamine release because of some
weird mystical ancient thing or whatever or sorcery,
it is chemically aldopa, the precursor to dopamine.
It contains some other molecules as well and low levels of other psychoactive.
This stuff is available over the counter.
Incredible.
I personally find it incredible.
Its effects are really interesting.
I'm not going to read them all off, but I mention these effects not because I'm encouraging
you to take it, but because you get a window into what dopamine, acute dopamine increase
does in the non-parkinsonian context.
And you can start to think about foods that are rich in L-tyrosine as biasing certain effects
are not others.
So when you hear food is medicine, food isn't really medicine, food is food, but food has these chemical effects as well. So first one listed is three studies with a very high
rigor that overall have a minor effect on of all things sperm quality. So it appears that sperm
motility itself, I'm assuming when they say sperm quality, I don't know what features of sperm of
quality they looked at, with sperm that's not a discussion I want to have,. I'm assuming when they say sperm quality, I don't know what features of sperm of quality
they looked at with sperm, that's not a discussion I wanna have,
but I'm assuming it's motility because I know enough
about reproductive biology to know that sperm ability to swim
depends on some proteins that are present in the front
of the sperm, et cetera, things like pentraxins
and sperm motility is generally associated with sperm quality.
Sperm that don't move are generally not very useful sperm.
Symptoms of Parkinson's disease are notably
degraded with macuna purine.
So fascinating, that's not surprising.
And there are a lot of other effects here,
feelings of subjective well-being, testosterone,
reductions in prolactin, not surprising.
Prolactin is a hormone that's involved in milk let down.
It's in lactating
mothers. It's involved in feelings of peace and generally is antagonistic to sexual desire
in both men and female. So it's really interesting that things like macuna perians, which RL
dope, a reduced prolactin increase, bone motility, increased testosterone, subjective well-being.
So you're starting to see a theme, right?
Dopamine really makes us motivated, feel in pursuit, makes us feel good.
Serotonin makes us feel more relaxed and calm.
Now this whole month is about emotions.
You might be thinking, well, wait, where are we going with all this?
Is it relates to emotions?
But in the last episode, I said something.
I'm going to repeat it now briefly, which is that much of what
we talk about is good emotions or bad emotions, there's a context to that, there's a social
context, you can't really say an emotion is good or bad, grieving at a funeral is healthy,
being happy at a funeral, assuming you loved the person that died, most people probably
wouldn't think that was healthy.
So we can't really say that certain,
emotions like sadness or happiness or healthy,
it's context is important, cultural context is important.
Many of you have asked for book recommendations.
This is an opportunity to raise a mention of another book.
Again, I don't have any financial affiliation
or anything, but if you wanna read more about emotions
and how the context and cultural things impact
our emotions, I'm a huge fan of Lisa Feldman Barrett. I learned about her from the Lex Friedman
podcast. I've had discussions with her on my Instagram live. She's at Northeastern University,
a world expert in emotions. Her first book is How Emotions Are Made. This is not a book she sent me.
I paid for this with my own money years ago, bought it,
read it, loved it long before I met Lisa. I'm just delighted that we've got to know each other
a little bit. It's a really interesting read into the psychology of emotions and some
of the subjectivity of emotions. So whereas I'm talking about mainly the biology of emotions,
this gets a little bit more into the psychology of the biology as well. And Lisa is just terrific.
She's also putting a lot of information out
into the world about emotions.
So if you want to learn more about that,
check out her work.
Again, it's Lisa Feldman Barrett.
And that book is how emotions are made.
Hopefully she'll continue to write many more books.
So now you understand the relationship,
I hope, between foods and dopamine, foods and serotonin.
And that they're both being communicated to the brain via the vagus, right?
We ingest these foods, where these supplements are things people take.
They don't put them directly into the brain, they put them in our gut.
So yes, there's a gut brain connection, but it's not about the serotonin in the gut
that makes you feel calm and plasid. It's not about the serotonin in the gut that makes you feel calm and placid.
It's not about the dopamine in the gut.
It's just been oversold that way
because I think there's something really attractive
and I understand about the idea that
because certain things about our experience of life
and our emotions is happening in our body,
that maybe we have a little more control, right?
Because this thing is a hard container.
We can't just stuff some dopamine in there.
I can't just, you know, I could probably take a macoon of purines, bean, and stuff in
my ear.
Please don't do that.
It'd make my ear itchy because of the serotonin on the outside.
But you can't get stuff in there.
What you have to do is ingest things that are metabolized in certain ways that communicate
to the brain.
Or so maybe they pass into the brain themselves
across what's called the blood brain barrier,
or talk about the blood brain barrier in a minute.
It's actually called the BBB,
so it ends up sounding like BBB.
I guess that's like BBB.
Anyway, BBB.
But there also nerves in the gut
that are sensing the nutrient contents of food,
and then saying,
oh, you should feel better and want more.
Oh, that's got a lot of bitterness and acid taste to it.
You should want less of that.
Okay.
So as I transition out of the discussion about dopamine and serotonin and the gut,
hopefully you've got some actionable items there under your belt pun intended,
where you can understand how certain foods and certain nutrients and you can look these up might impact your
Your mood if you're somebody who's really anxious and really wired well
Then the dopamine adrenaline pathway up an effort in pathways probably not one that you want to lean on any harder
If you tend to be someone who's pretty passive and you're having trouble with motivation. Well then, think about ramping up the dopamine pathway.
I always think behaviors and proper food choices
the best way to start and behaviors include things
like exercise, et cetera.
But one of the problems with the discussion around mood
and exercise or mood and meditation is that
it's so subjective.
It's like I love certain forms of exercise
and not others.
Certain ones are aversive to me.
Certain ones are attractive to me.
And it's never really clear.
No one's ever told me, okay, you have to do 10 minutes
on the bike at X number of RPM, at so and so
or on the skier in order to get your dopamine up.
But we can actually say, if you ingest more L-tyrosine,
there's a high probability that you're going to make
more dopamine.
And I'm talking about ingesting it through food or through supplementation.
If you like, McEunepurines, I've tried, I should just mention, it was too
dopamine-ergic for me. I really, really jazzed up and then
severe crash for me the next day. But that's, I think, because I tend to ride
pretty high on the kind of alertness and motivation scale. I'm always being told
by Costello and other people in the podcast of alertness and motivation scale. I'm always being told by
Costello and other people in the podcast studio to slow my speech down. This is me uncaffeinated
and I could probably afford a little more serotonin in my life. So whereas Costello, you get
a Ford, like, you get a Ford to wake up every, every couple days and just say hello to us.
This dog sleeps more than any other creature. It's remarkable.
this dog sleeps more than any other creature. It's remarkable.
So there are things that we can do, and they're actionable,
and they are in some ways they're quantitative,
because you can regulate dosages, and you can regulate amounts,
and you can regulate timing.
And everyone has to play with these things and figure out
what's right for them in terms of feeding,
and everyone has to explore and understand what's safe and right for them.
But, and of course, exercise is still very important.
I talked about social connection in the last episode, super important for activation of
serotonin.
But when it comes to this gut-brain-body-brain relationship, what we eat really matters
in terms of the neurochemicals that we make.
So, let's talk a little bit more about things that we ingest in our body and then allow
our body to then allow our
body to inform our brain to shift our mood.
And this is something I've been doing for years and I just want to say I've found to be
a complete game changer.
There's excellent science to support it.
And I think most people are familiar with it in a different context, but I don't think most people know this simple fact, which
is that the omega-3 to a mega-6 fatty acid ratio has a profound effect on depression.
It has a profound effect on mood.
So much so that in a double-blind placebo controlled study that I will provide the link to, this
was a study, first published in 2008, but there have been many others as well. First of all in
experiment done in animals they found there's a model of learned helplessness
in animals. It's not very kind to the animals but they put rats or mice in a
jar. They let them swim and they'll swim swim swim to try and save their life
and eventually they give up. It's a learned helplessness. They don't let them
drown. They take them out.
Adjusting the omega three omega six ratio so that the omega
threes are higher led to less learned helplessness, meaning these
animals would swim longer.
Okay.
Now that's an animal that's a rat, not a particularly kind study.
But that same study was essentially done in humans, although they
didn't have them swim to the point
of near drowning, what they did is they took people
who were clinically depressed, major depression.
Okay, major depression is severe maladaptive state,
meaning it inhibits job relationships,
appetite, all sorts of negative health effects.
And they did a comparison of a thousand milligrams a day of EPA.
So EPA is one of the elements that contains high levels of omega-3s.
That's in things like fish oil.
Talk about other sources in a little bit.
But it wasn't a thousand milligrams of fish oil.
It was a thousand milligrams of EPA, compared that to 20 milligrams of fluoxetine,
which is prosac, okay, really increases serotonin. And in this study of 60 individuals,
again, I'll provide the links to the study, they found that they were equally effective
in reducing depressive symptoms. So imagine that a food-based compound
that you can't make without, right?
This is not a situation where you can make your own omega-3s.
You have to get them from food sources
or from supplementation, was as effective
as 20 milligrams of fluoxetine over the course of eight weeks.
And what was really interesting in addition to that
is that the combination of 1,000 milligrams
of EPA and fluoxetine had a synergistic effect in lowering depressive symptoms.
I find this remarkable.
I heard about this when it first came out.
I wasn't sure what to make of it because there are a lot of studies that come out.
I generally like to focus my changes in behavior around things where there's a large center of mass. There's a lot of information.
A couple years later, I did, in fact, start taking a thousand milligrams per day of EPA in
fish oil. Now, there are a few side effects of fish oil. People who have blood, who are
bleaters, who have factor five light in mutations or in women who are taking
birth control, which can make you, which can affect blood clotting and things of that
sort, really should talk to your doctor, make sure it's okay for you.
Fish oil also can give people fishy breath, which is pretty gross, frankly, but they're
now fish oils that either because of the encapsulations or because of the, they put some lemon flavoring
in there doesn't have that effect.
In any event, a thousand milligrams per day of EPA, I started ingesting that regularly,
I just felt better.
I wasn't clinically depressed, but I did feel, at least for me, an increase in mood and
affect.
And a number of other things that's supposed to reduce inflammation.
The cardiovascular effects are controversial.
For a long time, everyone thought the effects on platelets were really terrific.
Then there are articles that came out in major newspapers saying maybe not so much, but
the effects on mood are really profound.
And now there are lots of studies.
If you go into PubMed and you were to put EPA or fish oil and depression, you would find
that there were a number of really
impressive results showing that it's at least as effective as certain SSRIs into depressions
at these dosages.
And it can amplify or improve the effect of low dosages of some of these SSRIs.
So I feel like more people should know about this.
This is nutrition, but it's profoundly affecting mood. And depression is terrible, right?
Depression can have a component of anxiety in some cases
where people are, they feel lousy and very uncertain.
That's kind of how I talk about depression with anxiety
is you know, you talk to someone who's anxious
and you can tell them everything's gonna be okay.
And they're always concerned about what might,
they might not know.
You don't really know the plane isn't gonna crash.
You don't really know that life is gonna go okay. And in sense the right no one has a crystal ball or can predict the future
But they tend to perseverate or fixate on the uncertainty and then of course
They're the versions of depression that involve certainty people are lethargic and they're certain they say yeah
I'm certain I'm never gonna get another job. I'm certain. I'm never gonna meet anyone new
I'm certain I'm gonna fail so there's's this kind of divide in the sphere of depression
around certainty and uncertainty,
but what's interesting is this 1000 milligrams per day
or more of EPA has been shown to relieve both forms
of depression.
Now, does that mean it's gonna work for everybody?
No, I'm not here to try and play psychiatrist.
I wanna point you in the direction of these manuscripts so that you can make informed
choices for yourself. You can discuss it with your doctor and family and make the choices
that are right for you. But here's what's especially interesting about the heart effects. Because
we've heard that these omega-3s, which of course you can get from other sources too, you
can get from fatty fish, there are flax seeds, hemp seeds, there are a number of
chia seeds, these kinds of things, but the levels of EPA that are required are quite high, so this
thousand milligrams per day. That's pretty hard to get from food, although it can be done, depending
on what you're eating. What's interesting is that the heart effects that are solid that really stand up in the
literature have a lot more to do with something we talked about in a previous episode.
Now I'll mention again, which is heart rate variability.
So we know that having a heart rate that's really high or a heart rate that's really low,
neither of those are good.
A lot of people think, oh, you just want a low heart rate, big stroke volume.
You know, if you're running a lot, you may 30 or 40 beats per minute,
that's great to be in shape,
but you still want heart rate variability.
It has a lot to do with the tone
of the autonomic nervous system.
I talked about last time, how when you inhale,
it speeds up heart rate, when you exhale,
it decreases heart rate, that's called respiratory sinus.
Arrhythmia, it's the basis of heart rate variability.
We'll maybe do a short post about this
so you can get all the mechanism and the behaviors
that spill out of that that might be useful for you.
But the point is heart rate variability, HRV, is good.
And what's interesting is that there was a study in 2009 that showed that people who eat
a diet and fail to supplement in a way that there's a high omega-6 to 3 ratio,
so not enough omega-3s. Not only are there markers of inflammatory cytokines elevated,
things like IL-6 and TNF alpha, but they tend to be non-responders to antidepressants.
Shifting that omega-3 omega-6 ratio did a couple things. First of all, increasing the amount
of EPA shifted the ratio, so it was higher omega 3 to
omega 6 ratio, which was good, lowered the inflammation markers, and then allowed antidepressants
to have their effect even at low doses.
And here's the really interesting thing.
It worked by increasing heart rate variability.
And I thought, you think, well, how in the world would this happen?
But, you know, I mean, that's a ton of effects.
But the way it works is because of the way that these things
are impacting the gut and the autonomic nervous system.
Remember earlier, I said the vagus includes connections
from the heart signaling about sensory information
about how fast the heart is beating to the brain,
not just stuff from the lungs, but information from the heart,
and the brain then adjusts heart rate
by heart rate variability.
So it's incredible that there's a way that one can
use the gut, the ingestion of more of these EPAs,
either through food or supplementation,
to increase heart rate variability,
and thereby to improve symptoms,
meaning reduce symptoms of depression, and to even
make low levels of antidepressants that wouldn't otherwise work work.
And I think I like this study so much because, hey, it's super cool.
It bridges the brain body access, it incorporates nutrition and micronutrients and the brain,
but also because it really points to something that we hear all
the time, which is that our body is a whole system.
It's working as a whole system.
The brain isn't working in isolation up there in the skull.
It's reacting to things that are happening in the body, in the gut, in the heart rate
and heart rate variability, and that the things we ingest can have a profound effect on them.
Now, of course, I really want to emphasize something, which is that no one compound or nutrient or supplement
or drug or behavior for that matter is going to be the be all end all of shifting out of
depression or improving one's mood or improving sleep.
It's a constellation of things.
And this is especially true when people start to get excited about supplements and drugs
of all kinds and
their potential for various things. Right now, there's a lot of excitement about psychedelics and their therapeutic uses,
and I think great, but as a good friend of mine who's a physician clinician says,
better living through chemistry still requires better living. You cannot expect to take a compound
regardless of source or potency and
Have it completely shift your experience of life without having to continue to engage in the proper behaviors
All the things we know proper sleep exercise social connection food, etc. There are many others as well
so I still find that this
Collection of studies about omega-3 omegaomega six ratios to be profoundly important,
so much so that it's completely changed the way that I think about food, the foods I eat,
I do supplement, I don't necessarily that think that's for everybody, but I really think
it's incredible that there are these compounds that have these robust effects on our feelings
of well-being.
And there are others too.
So that thousand milligram per day threshold of
fish oil that's beneficial requires that one take a reasonable amount of these things
either through food or through supplementation. I acknowledge that not everyone wants to take
fish oil. There are a couple reasons why one might want to avoid that. One would be for
ethical reasons. You have an emotional relationship or a relationship to the environment that makes you not want
to ingest fish-related products.
There's krill oil, krill is still in organism, and it's a little tiny thing that whales eat
a lot of, and people generally eat very little of.
So krill is out there.
I personally just me, I don't know why.
I didn't racked well to krill.
It didn't make me feel very good.
I had some skin it, and things like that.
They stopped when I stopped taking it, but I don't want to bias you against it if that's
your preference.
Some people really like krill oil as a source of omega-3s.
I did mention some of the other sources like chia seeds and flax seeds, but you'll notice,
these are not things that we tend to ingest a lot of on a regular basis.
It is possible to get omega-3s from meats if the animals have grazed on grasses that contain a lot of omega-3s.
So for those of you that ingest meat, you know, the source of those meats is going to be very important as it relates to omega-3s.
Even within the category of fish oil, there's a concern sometimes about mercury
and other contaminants. You want to go with a brand that emphasizes that they've gone
to really good sources and that they decontaminate regardless. And so you have to search out
those brands. There is a test that you can do as to whether or not the fish oil is rancid
or not. Some people take in liquid form, some people take in capsule form.
The liquid form is going to be more affordable. The capsule form is a little
easier and a little more portable. You can actually just chew one of the gel
tablets and if it tastes really fishing kind of rancid, you'll know it's
disgusting, you want wanna spit it out.
And if it doesn't and it's tolerable,
then you'll know that it's okay.
Unfortunately, you have to buy it first in order to do that,
although I don't know, maybe you can get them
to open up the bottle for you in the store
and tell them that you don't wanna try it.
Someday, perhaps, fish oil and omega-3s,
it'll be like tasting wine at a restaurant
where you can send it back for now.
I think you have to purchase it first,
but find a brand you trust and like and then work with them.
If you decide to go that route, of course. There are other compounds that are
also interesting for mood elevation that are essentially like foods or are
supplement based that now fortunately there are really good data from pure
viewed studies.
And the next one I want to mention
because I think it's really interesting is Elkharnitine.
Now Elkharnitine has been around a long time
and it's been discussed in the context of heart health
and a number of other things.
It was actually in tout is a bit of a weight loss agent
in the early 90s.
But Elkharnitine actually has some really impressive effects on depression.
And again, we will look to PubMed because looking at examine.com is essentially for me,
anyway, looking at PubMed, what is Elkharnitine?
Elkharnitine is most prevalent in meat and in beef in particular.
Now, for the vegans, please know that Elkharnitatin is available through non-meat sources as well,
although it's not as enriched in non-meat sources.
It's a really interesting molecule because elceital alkanatin is essentially what's made
from alkanatin, but it's acetylated.
If you're interested in the biochemistry, you can look that up.
It's acetylated into a form that can cross the blood brain barrier.
The blood brain barrier or BBB is a barrier.
It's a wall around the brain.
You have this barrier because the brain is so important and it has this feature that the
neurons there don't recreate themselves after injury, like other organs of the body.
There's not a lot of turnover of cells, despite what you might have heard.
Nature has created this BBB, this blood-brain barrier, to make sure that certain molecules,
in particular large molecules, don't get across the blood-brain barrier, because it can be
damaging to those tissues.
Incidentally, you also have a very rigid or stringent barrier around other organs, which are
the gonads.
So the ovaries and the testes and the brain are the organs of the body that nature has
gone out of its way to protect, give this additional layer of the blood brain barrier,
or as you might imagine, for the testes and the ovaries, it's going to be the blood gonadol
barrier.
So these barriers exist and make it such that just because you eat something, just because
you ingest it, doesn't mean it's going to cross the blood brain barrier. These barriers exist and make it such that just because you eat something, just because you
ingest it, doesn't mean it's going to cross the blood-brain barrier.
But alcharnitine, when taken, is acetylated and converted into this form that gets across
the blood-brain barrier, and it has a lot of effects it's involved.
It might have conjural activation along chain fatty acids, which that's a big mouthful
that we can get into sometime when we're talking about metabolic.
But it has some interesting effects on the neuroside.
So if you decide to check it out on examine.com, you'll see some really interesting things.
Lots of effects on ammonia, see reactive proteins, things of that sort, blood glucose is lowered,
et cetera.
That's all stuff that's the level of blood and periphery, slide effects in lower and
cholesterol.
Here's some interesting ones.
Rates of pregnancy go way up when people are taking
alkanitine, both the father and the mother,
both the source of sperm and the source of egg,
are affected in ways that favor pregnancy.
It does increase, here we go again,
with sperm quality, sperm motility,
in males, and it seems to have positive effects on females that have polycystic ovary syndrome.
So check that out. The effects are very strong. There are three studies listed there. Again,
I'm not promoting this, but that people take alcharnitine, especially if you're trying
to get pregnant, but check
it out because the effects there and the studies that are mentioned are published and peer
reviewed rigorous journals.
In terms of the neural effects, those are quite interesting.
The effects on depression are still emerging, but they do seem to exist, that people feel
a notable decrease in depressive symptoms.
There are seven studies listed on examine.com that has a notable benefit of a variety of circumstances
where participants have heightened depression already.
They start taking alchornitine and they start feeling better and they talk about dosages
in those various studies.
It also has been shown to have a notable decrease in the symptoms of autism, which I find fascinating.
Also, again, the things we ingest impact the chemicals in our brain and how they impact the rest of our body.
There's other things that's been used to treat certain forms of alcohol dependence.
I think this is going to be a very exciting emerging area.
We're going to do a whole month about addiction.
I've got a great guest lined up for that month, but there's now an emerging field about what people can take
and supplement to help ease the cravings and the withdrawal when trying to quit drugs
of abuse, like cocaine, alcohol, heroin, and smoking and things of that sort. So really
interesting area, this is I like to think is early days and then we're going
to discover a lot more.
There's a huge list of things here since we talked about pain in a previous episode and
I know a lot of people have written to me about fibromyalgia.
It does, quarantine has been shown to reduce symptoms of fibromyalgia.
Again, all the links to studies are on examine.com, totally free site.
And that was my bulldog being a battering ram.
There's nothing graceful about this bulldog.
He's decided he wanted to leave to go get drink of water.
And so please forgive the noise.
Okay, so now let's turn to another aspect of the gut brain relationship that will surprise
you, in some cases might shock you, and that has some really cool and actionable biology.
And that's the gut microbiome, probiotics, and prebiotics.
I know today we're talking about emotions and not pain,
but I'd be remiss if I didn't mention
another effect of acetylocarnitine that's been reported,
and that you can find listed with link to study
on examine.com, which is its effect
in reducing the symptoms of migraine.
This was a randomized control trial with 133 participants who had frequent migraines.
They were taking 500 milligrams of alcharnitine or nothing for 12 weeks.
So the control experiment there is a little bit tricky,
but it had a significant effect on reducing the number
of migrant attacks per month.
So I find that really interesting.
And there's a lot more listed there about the study.
And I think these compounds are powerful.
They carry risks for certain people, not for others.
So again, you have to find out what's right for you,
but I do think they are super interesting
as potential therapeutics for various people.
So what's the deal with the gut microbiome
and the gut brain access?
Today we've actually been talking a lot already
about the gut brain access that has nothing to do
with microbiomes.
We've been talking about this vagus nerve that connects providing sensory information from
the body to the brain, and then the brain also sends in the same nerve motor information
to control the motility that got the heart rate, how fast we breathe, and deployment of immune
stuff killer cells and things of that sort.
But oftentimes, when we hear about the gut brain access
these days, it's a discussion about the gut microbiome.
And once again, we're in a situation
where there's incredible biology.
I'm very happy there's so much discussion
about the gut microbiome.
I am somewhat dismayed and concerned that most of what I hear out there
is either false or partially false. So we're going to clear up some of the
misconceptions. First, by understanding the biology and then we're going to talk
about some of the actionable items. It is true that we have a lot of these little micro organisms living in our gut.
They're not there because they want to help us.
They don't have brains.
They are adaptive, however.
They try and find and create environments that make it easier for them to proliferate.
So they don't care about you and me, but they are privately willing to exploit you and me
in order to make more of themselves.
The same way viruses are.
Viruses don't have a mind.
They infect cells.
They hijack the genome, and they use that genome to make more of themselves.
The microbiota that live in us very along the length of our digestive tract.
But let's just take a step back and think about how our body plan is made.
We are actually a series of tubes.
Our brain is actually a tube.
You see it's all squishy on the outside, and then it's got that long thing, the spinal
cord that goes down to the base of the spine.
That's the central nervous system.
That all started out as a tube.
It just looks like a cauliflower on the other end up in the brain because the tube is so big
and it has to be crammed into the skull so it gets all wrinkled up.
But if we were to display it out, you'd find it's just one big tube.
Similarly, our digestive tract and our airways are essentially one big tube.
It starts with our mouth, also our nose, and then we have all these other tubes that go
down through our throat and then into our stomach and then into our various intestines and then
the tube ends out the other end.
So we are one long tube for digestion.
And inside of that tube is a mucosal lining.
It's these little microvillag, tiny, tiny, tiny, little like velvety ends of cells that are able to move and move things
along.
And mucus, mucusa.
And the conditions of that mucusal lining set a number of different things.
It sets the rate of our digestion and the quality of our digestion.
It sets, for instance, our immune system.
Most people probably don't realize this,
but most infections in the environment,
well, they have to get into our body somehow.
Some of them are inhaled.
A lot of them going to our mouth
and lodge in the mucusal lining of the mouth,
and then infections start there.
You probably had the experience, unfortunately,
of feeling like you have a tick in your throat,
like something's irritating your throat,
and then it kind of migraines up into a head cold,
or runny nose.
Sometimes they'll start as a headache,
sometimes it won't.
But things that can migrate down into the gut,
so we're ingesting things all the time,
thinking about air bacteria, viruses,
they're making their way into our gut,
and some of those bacteria live in the gut,
and some of those bacteria live in the gut. And some of those bacteria
bias the mucosal lining in the gut, stomach and intestines, to be more acidic or more
basic so that they can make more of themselves. So they can replicate. They like a particular
comfort. It's like they like a particular kind of bedding to lie down in and create more
themselves. Now, some of those mucosal linings that they promote make us feel better. They
make us feel more alert. They bolster our immune system and others make us feel worse.
So first rule, the microbiome isn't good or bad. Some of these little bugs that live in us do bad things to us.
They make us feel worse.
They lower our immunity.
They affect us in negative ways.
Some of them make us feel better.
And they do that mainly by changing the conditions
of our gut environment.
In addition to that, they do impact the neurotransmitters
and the neurons that live in the gut and that signal
up to the brain to impact things like dopamine and serotonin that we've been talking about
previously.
So there's a vast world now devoted to trying to understand what sources of food, what
kinds of foods are good or not good for the gut microbiome.
So let's just talk about some general rules of thumb related to the research, quality
research that's peer reviewed.
And then in a future episode, we will go far deeper into the gut microbiome and gut brain
axis.
But here's a few things that I think you might find surprising.
First of all, supporting a healthy gut microbiome is good for mood, great for digestion, and great
for immune system function.
However, that does not mean maxing out or taking the most probiotic and prebiotic that
you can possibly manage.
As I mentioned many times before, I do believe in probiotics, I take probiotics, but there
are studies that show that if you take lots and lots of certain probiotics like lactobacillus
and you really ramp up the levels more, it is not a case of more is better.
There are things like brain fog that can come from that.
Brain fog is just this inability to focus.
People feel really not well generally.
Some of those studies are a little bit controversial,
but I think it's fair to say that if people
really increase the amount of probiotic
that they're taking beyond a certain amount,
then they start feeling foggy in the mind.
Now, what's too much?
Well, I get probiotics from, I've mentioned before,
from Athletic Greens.
You can get them from fermented foods, like sourcrout, pickles, kimchi, natto, these are different sources from
around the world.
Actually, I'd love to hear some of the other sources that people know, other foods from
around the world, I'm fascinated by the way in which different cultures have all arrived
at these foods that provide and support healthy microbiomes because they're fermented.
I have a colleague at Stanford, Justin Sonnenberg, and he and I have talked about this.
I don't want to quote him inappropriately, but we've had discussions about and they've
published that the ingestion of fermented foods is one of the best ways to support healthy
levels of gut microbiota without exceeding
the threshold that would cause things like brain fog.
So foods and fermented foods are going to be the best source.
And there are a number of different ways that one could do that.
Some people don't like fermented foods, however, some people supplement it.
So it isn't a case of moris better.
Okay, so we know that. The other is that it is true that healthy gut microbiota have been shown to improve symptoms
of certain psychiatric illnesses, as well as certain conditions like particular features
along the autism spectrum, which is interesting.
And those effects are probably due to not just improvement of immune system function,
but to the conditions in which the neurons that sense nutrients convey information to the
brain and increase levels of serotonin and or dopamine.
So gut microbiome provides kind of a foundation for healthy gut and healthy gut brain access.
So much so that some people report that when they start
eating small bits, because it doesn't require a lot
of fermented foods, that their overall mood is better,
not unlike the effects of EPA,
although I don't think it's been looked at
directly in the context of clinical depression yet.
And if someone knows of a study,
please mention it in the comments.
That would be terrific.
There are some things that you can do
to really damage your gut microbiome.
And this is where there's a huge misconception that I want to clear up. There's a study that was published in Nature,
which is among the three top journals that we have in Science, Nature, Science, and Cell, or considered the top tops,
but excellent journal that showed that artificial sweeteners, but a particular artificial sweetener, which
was saccharin, can disrupt the gut microbiome in ways that is detrimental to a number of
different health markers, increasing inflammatory cytokines, and all the other bad things that
happen when the gut microbiome is thrown off-kilter.
That study was widely discussed,
but there were a few things that were not mentioned there
that are really important.
That study was about saccharin in particular.
Saccharin is not the most typical artificial sweetener
that's used.
The most typical artificial sweeteners
that are used are things like aspartame,
so-called neutro-sweet or sucralose, or these days stevia, there's monk fruits to my
knowledge. And please correct me if anyone knows of any stice to my knowledge. The
negative effects of these artificial sweeteners on the gut microbiome were
restricted to saccharine. Now there is enough chemical similarity between saccharin and some of the other ones that
I mentioned, but not all of them.
For instance, stevia, monk fruit are distinct in their chemical makeup so that they probably
don't have, if they have any, have lower effects, negative effects on the gut microbiome, but
it should still be tested.
So saccharin is really, it was shown in this study and several other studies, can really
negatively impact, excuse me, the quality of the gut microbiome.
Interestingly, the narrative around artificial sweeteners in gut microbiome is incorrect.
Most people thought, oh, saccharin is bad for the microbiome.
It must kill the microbiome.
And so you hear people saying, oh, you know, artificial sweeteners kill the microbiome.
That's not true at all.
In fact, in that very same study published in Nature, they showed that the negative effects
of saccharin on the microbiome could be blocked or eliminated by giving antibiotics.
So what happens is certain artificial sweeteners, in particular saccharin, disrupt
the microbiome and make the environment within the gut that mucosal lining more favorable
to bacteria microbiota that are not good for the organism. Okay, this is an important distinction.
It's not just that a language thing where people say, oh, you know, it kills the microbiome.
It doesn't kill the microbiome.
It shifts the microbiome.
And shifts in the microbiome can be good or they can be bad.
And that takes us to another topic.
That's a bit of a hot button topic,
but I'm willing to go there
because I think it deserves conversation,
which is nowadays, there are many examples out there
where people have switched from a kind of standard diet
or even a vegetarian diet to a vegan diet to a keto diet.
Now, keto doesn't necessarily have to mean the ingestion
of meats, but it can.
And they experience positive effects for themselves,
not everybody.
And I've talked previously about some of the, kind of the incorrect,
what I believe is incorrect, marketing of keto
as it relates to the cosmetic effects
and some of the challenges with sleep that some people have.
But some people love keto and it works great for them.
But the ketogenic diet is interesting
because when one shifts to the ketogenic diet,
there is a shift in the gut microbiome
and some people end up feeling better.
Some people end up feeling better. Some people end up feeling worse.
Likewise, some people go from ingesting animal products, including meat or their vegetarian
and they go to vegan, and they experience positive shifts in mood and affect.
We know that the transition to a more plant-based diet, and especially the enrichment of fiber
that's present in those diets, also creates dramatic shifts in the gut microbiome.
Some people feel better doing that.
Some people feel worse.
And of course, it's going to depend on whether or not you're ingesting a lot of processed
foods or not.
There was a paper published in Cell, a Cell Press Journal, obviously, excellent journal,
showing that ingestion of processed foods regardless
of whether or not they come from animal sources or non-animal sources, the processed foods
themselves tend to create activity within the body and this surely has roots in the nervous
system that lead to overconsumption of calories and weight gain, even some weight gain that
couldn't be explained by increased calories.
In other words, processed foods are bad regardless of whether or not you're talking about animal
products or non-animal products. Probably not surprising now given what you know
about these sugar sensing and other amino acid sensing cells in the gut that we
talked about earlier. So the point of all this is that when I say you have to
find what's right for you, that's not a throwaway statement. Some people's microbiome and the lining of their mucosa, excuse me, their mucosa lining
of their throat, of their gut, of their nose, everything is improved by diets that are
heavily meat-based and don't have many plants.
Other people do much better on a plant-based diet without many meat products or animal
products.
It's highly individual.
And this probably has roots in genetic makeup.
This probably has roots in what people were raised on.
Because remember, the nervous system, of course, is set up by your genes, your genetic program,
but your nervous system adapts early in life to your conditions.
That's what it's for.
The reason you have a nervous system is to move your body appropriately
towards things that are good for you
and away from things that are not.
But also, it was designed to adapt.
The early life period has this incredible thing
about plasticity that we spent a whole month on
so that it can change so that, yes, indeed,
some people may like certain foods
and react to certain foods better than others
because of the way that their nervous system
was wired, this enteric as way that their nervous system was wired.
This is an enteric, as it's called, nervous system that lines the gut and that communicates
with the brain.
So, most of what I've talked about today is black and white.
These are things that are present in all of us.
The sugar sensing neurons of the gut, the way the vagus is wired, the fact that omega-3
omega-6 is tend to improve, the ratios tend to impact mood with high omega three omega six ratios improving mood.
We talked about all sorts of things
in the gut brain and body brain access.
But when it comes to the microbiome,
the key thing is that we all have a microbiome.
You want a microbiome, but you want to promote
the microbiome that is right for you.
And that can be shifted and steered by ingesting certain categories of foods and not others.
And one thing that really frustrates me is when people show up with an agenda like, you
know, a all-me agenda or a vegan agenda or a keto agenda, and they talk about these
positive effects on the gut microbiome, and it's all true, frankly.
And so it's highly individual.
Now this doesn't get to any of the ethical issues around animals or the planet or, and
you hear rabid debates about that, you know, on both sides.
And I am not a qualified or equipped to talk about whether or not, you know, regenerative
out, agriculture or animal products or farming or any of these things, how those actually
impact the environment.
That is not my expertise.
But when it comes to your health and your microbiome, you want to support the microbiome.
It's very clear that these fermented foods support the microbiome, that we should be
ingesting at least two servings per day, which is quite a lot, that supplementation at
low levels can be good.
Supplementation at high levels can create this brain fog.
Even though some people say that result is controversial,
I've experienced this myself and the data
looked to me pretty darn solid.
So that's one thing to think about as well.
And the other thing about the gut microbiome
is that it's highly contextual based on other things
that you're doing.
So even things like exercise and social well being
and connection, those things are also impacting the gut microbiome. So find the diet that's right for you and that works for you
in the context of the other ethical and lifestyle choices that are important to you. That's my advice.
A note about fasting. I have a colleague at Yale who's an expert in the gut microbiome and he told me
something really interesting, which is when we fast, we actually digest certain
components within our dietary track. It actually depletes a good amount of the gut microbiome.
And this is interesting. I've had good results from, I guess you would call it intermittent
or kind of circadian type fasting, where I've never done long fast, but where I push out
my first meal by a I push out my first meal
by a few hours, my first meal is generally around lunchtime or so.
But the longer periods of fasting
that go for a day or two or three days
are known to deplete the gut microbiome in major ways.
And, but that's not always necessarily a bad thing
because when it's replenished,
it often is replenished at levels that exceeded its previous
level.
But I think that some of the GI tract and even some of the mental effects of returning
to eating after feeding, sometimes people don't feel so good when they start eating.
They really want food, but then they start eating.
Again, they don't feel as good as they did on the fast.
Some of that may be related to the depletion of the microbiome that occurs during long
fast.
So again, this is something to think about and talk about with your doctor, but the idea
that fasting across the board is good.
There may be some merits to that, and certainly in some cases, but it does deplete the microbiome.
And that depletion of the microbiome is significant because it means when you return to eating, you
are actually not in the same position to digest and assimilate those foods and those foods are not in the same
position to impact your brain and body the same way they were prior to the fast.
This is I think why people suggest a kind of gradual transition back to consuming nutrients
after a fast.
So as we round up, I want to share some results with you that Without question will impact the way that you respond to food mentally and even physically and I know that because
That's the central theme of the studies. I'm about to tell you about I have a colleague at Stanford
Aliyah Krum who's done some remarkable experiments on
mindset and
Some people could think about these as placebo effects
or belief effects, but they actually
go way beyond those terms.
And there are a number of different examples of this
that Alia's lab and her coworkers have demonstrated.
But two that are particularly interesting to me,
I want to share with you now, because they really emphasize
how our beliefs
can really impact the way that our brain and body work together.
I think the most famous of these is an experiment they did
where they had two groups of individuals.
They were each given a milkshake,
and they had some factors measured from their blood
by an IV while they ingested the milkshake
and then afterwards
as well.
And one of the factors that they were looking at was something called grillin, GHR, ELIN.
Grielin is a peptide that increases with hunger.
So the longer you have an eaten, the grilling goes up.
And I know some of you say, well, I fast, I fast, I fast, and I eventually lose my appetite.
Well, grilling still goes up and then it drops.
So if you were one of these people that eats
every three hours regularly,
Grelin kind of gets a little pulse
as you get to that two hour and 50 minute mark.
So it's a little bit of a timer as well.
It's a really interesting peptide.
In any event, what they did is they gave people milkshakes
two groups.
One group got a shake that they were told was a low calorie, healthy shake.
The other group got a milkshake that they were told was the very decadent high calorie
shake.
I think it was something like two or maybe even two and a half times as many calories
as the other.
Perhaps even more.
I don't recall the details, but you had a high calorie and a low calorie condition.
Then they drank the shake and then then they measured Grielin in these subjects of blood.
And what they found was that the high calorie shake had a much more robust effect on blunting
Grielin and reducing Grielin.
But the interesting thing, you probably guessed already, is that it was the exact same shake given to both groups.
So people's belief about the content of something impacted their physiology.
And this speaks to the so-called top-down mechanisms or modulation of our physiology.
In a previous episode about pain, we talked about the effects of obsessive, believe
or not, it was the kind of obsessive infatuation and love on pain responses and pain thresholds.
This is yet another example where beliefs or subjective feelings can impact physiology
at the level of the periphery because greediness is released in the periphery in the body.
Now these belief effects extend beyond examples like this another good example that I'd like to share is
Allie doctor Crom and her colleagues did an experiment where they took
Housekeepers hotel they were essentially hotel workers divide them into two groups
They had them watch a short film in one case the film was about how you know their work was important
It helped people feel comfortable in the hotel, et cetera, et cetera.
The other group heard that the activity that they were doing cleaning and taking care
of the hotel was good for them.
It was good for their health, et cetera, et cetera.
They controlled very nicely in the study for health parameters, for individual differences,
and for the behaviors of these people in the period that followed this short tutorial.
And what they found was eight weeks later, the group that had been told that the activity
was good for them showed lower blood pressure.
They had lost a significant amount of body fat, and they reported enjoying their work far
more than the other group.
The same work, simply biased mentally by the
information that they were given, but their physiology followed that information. And so,
this is not just the placebo effect. This is an incredible set of findings that illustrate
the extent to which whether or not we believe a food is going to be good for us or not
good for us. Well, we can't escape the reality. You can't tell yourself that a poison is going to be good for
you and ingest that poison and expect it to not kill you. Nor can you tell yourself that eating
you know 12 croissants, confess I've done it. It was after a very long run a long time ago,
but you can't tell yourself that that's necessarily going to be good for you or that it's going to make you lose weight.
These belief effects are not about lying to yourself.
In these cases, in these experiments, as you'll notice, the subjects didn't have prior knowledge
about grillin or about the effects of their daily routine on weight loss and blood pressure.
In order for them to work, you have to be naive to the information. Right? You can't
simply lie to yourself and tell yourself what you want to believe. And that's important, but also
important is that the mind and the body are in this fascinating interplay. And today we've talked
mainly about how the body and things that we put inside this tube, this that runs from our mouth to
things that we put inside this tube that runs from our mouth to the other end, to our rectum, basically, is impacting all these cells, these neurons, microbiota in their
neocosal lining, heart, lungs, and how all that information is feeding up to the brain to
impact how we feel up here.
But also how we feel up here is impacting how our body reacts at levels of very core
physiology that you couldn't just tell yourself that this was going to work.
But what you believe about certain substances, certain foods, certain nutrients does have
a profound effect on the magnitude of their impact and sometimes even the quality and direction
of that impact.
Well, first of all, I want to thank everybody
for their support of this podcast,
the response that we've received since releasing
at the beginning of the new year,
has been tremendous and we're so grateful for it.
I know some of you, and people you know,
I've said, well, it's a lot of information,
it's like a college lecture.
Indeed, there's a lot of information,
but I believe very strongly that if you learn mechanism,
and maybe even if you hear it several times over, eventually those mechanisms become embedded
into the way that you view an entire topic.
As well, I always try and put tools as I go along that you can look to immediately.
Some of them might be right for you, others might not.
Try them if you like, and don't if you don't want to, and if they don't work for you, then
discard them. If however you are finding benefits from the information
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If you go to livemomentus.com slash huberman, you will find many of the supplements that
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So today's episode we took a full journey into the brain body relationship and discussed a lot of
the mechanisms and the actionable items that you can approach if you want to explore this aspect
of your biology and psychology further. Last but certainly not least, I want to thank everybody
for your time and attention today and as, thank you for your interest in science.