ANDREW HUBERMAN: Welcome to Huberman Lab Essentials,

where we revisit past episodes for the most

potent and actionable science-based tools

for mental health, physical health, and performance.

[MUSIC PLAYING]

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.

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.

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 in the context of food

and nutrition.

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 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, mm, 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 intense aversion 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 tastes 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 what we call

higher order evolved centers of the brain,

we have this push-pull thing.

In a 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 de-emphasize action and prevent action.

And so we can break down the discussion about emotions

into these simpler versions of themselves.

But at the core 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.

The brain 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.

So there are circuits in the brain for aversion

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 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.

So what is the vagus nerve?

Vagus is the 10th cranial nerve, which basically means that

the neurons, the control center of each of those neurons

in the vagus lives just kind of near the neck.

And a branch of the vagus goes 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 the way to think about the vagus

is the same way I would think about the eyes.

The eyes are looking at colors.

They're looking at motion.

They're looking at 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.

So that makes sense, right?

You eat something, it tastes 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.

And what it tells us is that we have circuits in our body

that are driving us toward 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 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.

I mean, this should completely reframe the way

that we think about the 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 piece of bread,

or even like a salad dressing, if there's 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.

So I find this to be a fascinating aspect

of our biology.

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 help, 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 the sum 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.

Its 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.

OK, so we've heard dopamine is this molecule that

makes you feel good.

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.

It's called 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.

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.

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, et cetera, that make dopamine.

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 l-dopa.

People with Parkinson's take l-dopa and other compounds

to increase dopamine.

Because Parkinson's is associated

with deficits in movement.

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 some famous examples would be,

you know, Muhammad Ali, Michael J. Fox, the great boxing

trainer, Freddie Roach.

These people have Parkinson's and they, at least later

in their life, had challenges speaking.

Now some people immediately ask, well,

should I supplement l-tyrosine?

It does increase kind of mood and elevation and alertness.

It is over-the-counter.

You have to check with your doctor--

I am not responsible for your health care,

and I'm not a doctor--

whether or not it's safe for you.

People with pre-existing hyperdopaminergic 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 increase dopamine levels.

That's well known.

Taking chronically, however, it can disrupt

those dopamine pathways.

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 toward 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 l-tyrosine 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.

So the other neuromodulator that's

really interesting in the context of the vagus

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.

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.

The conversation around the brain, body, relationship

and mood and 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,

have 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.

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 raphe nucleus of the brain.

There are a few other locations, too.

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.

The first one and most famous one

is Prozac, Zoloft, and Paxil, a number

of other ones that are so-called SSRI, selective serotonin

reuptake inhibitors.

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 overall, which

means to elevated 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.

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.

Many people adjust their serotonin

by just eating more food.

And carbohydrate-rich foods will increase serotonin.

I eat a relatively high protein and

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 tryptophan.

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 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.

So let's talk a little bit more about things

that we ingest in our body and then allow

our body to inform our brain to shift our mood.

But I don't think most people know this simple fact.

Which is that the omega-3 to omega-6 fatty

acid ratio has a profound effect on depression.

First of all, in an 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-3 and omega-6 ratio

so that the omega-3s are higher led

to less learned helplessness, meaning these animals

would swim longer.

But that same study was essentially done in humans.

What they did is they took people

who were clinically depressed, major depression--

major depression is severe maladaptive state,

meaning it inhibits job, relationships, appetite,

all sorts of negative health effects--

and they did a comparison of 1,000 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.

But it wasn't 1,000 milligrams of fish oil,

it was 1,000 milligrams of EPA.

Compared that to 20 milligrams of fluoxetine, which is Prozac.

They found that they were equally effective in reducing

depressive symptoms.

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.

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, antidepressants,

at these dosages.

And it can amplify or improve the effect of low dosages

of some of these SSRIs.

You can discuss it with your doctor and family

and make the choices that are right for you.

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 all, end all of shifting out of depression,

or improving one's mood or improving sleep.

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, et cetera.

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.

So what's the deal with the gut microbiome

and the gut-brain axis?

Today, we've actually been talking a lot already

about the gut brain axis 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, the gut, the heart

rate, how fast we breathe, and deployment of immune stuff.

But oftentimes when we hear about the gut-brain axis

these days, it's a discussion about the gut microbiome.

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 microorganisms

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 perfectly willing to exploit you

and me in order to make more of themselves.

The microbiota that live in us vary along the length

of our digestive tract.

So we are one long tube for digestion.

And inside of that tube is a mucosal lining.

And the conditions of that mucosal 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.

We're ingesting things all the time.

Think 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 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.

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?

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.

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 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.

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 was a study 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.

Saccharin is not the most typical artificial sweetener

that's used.

The most typical sweetener.

Artificial sweeteners that are used

are things like aspartame, so-called NutraSweet,

or sucralose, or these days, stevia.

To my knowledge, the negative effects

of artificial sweeteners on the gut microbiome

were restricted to saccharin.

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.

This is an important distinction.

It's not just that a language thing

where people say, oh, 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, or 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.

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 worse.

Likewise, some people go from ingesting

animal products, including meat, or they're vegetarian

and they go to vegan, and they experience positive shifts

in mood and affect.

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 mucosal lining of their,

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 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 it's called, nervous system

that lines the gut, it communicates with the brain.

So most of what I've talked about today

is a 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-6s tend to improve--

the ratios tend to impact mood with high omega-3 and omega-6

ratios improving mood.

We talked about all sorts of things

in the gut-brain and body-brain axis.

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.

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.

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.

I have a colleague at Stanford, Alia

Crum, who's done some remarkable experiments on mindset.

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 ghrelin, G-H-R-E-L-I-N.

Ghrelin is a peptide that increases with hunger.

So the longer you haven't eaten, the ghrelin goes up.

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.

And what they found was that the high-calorie shake

had a much more robust effect on blunting ghrelin and reducing

ghrelin.

But the interesting thing you probably guessed already

is that it was the exact same shake given to both groups.

And this speaks to these so-called top-down mechanisms,

or modulation of our physiology.

In a previous episode about pain,

we talked about the effects 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 ghrelin is released

in the periphery in the body.

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, these belief effects

are not about lying to yourself.

So in order for them to work, you

have to be naive to the information.

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 that

runs from our mouth to the other end, to our rectum, basically,

is impacting all these cells, these neurons, microbiota

in there, mucosal 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.

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 always, thank you for your interest in science.

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