Huberman Lab - Understanding & Conquering Depression
Episode Date: August 23, 2021This episode, I explain what major depression is at the biological and psychological level and the various treatments that peer-reviewed studies have revealed can help prevent and treat depression. I ...explain the three major chemical systems that are altered in depression: norepinephrine, serotonin and dopamine. I discuss genetic predispositions to depression and how stress, thyroid hormone and cortisol play a role in many forms of depression. I also discuss inflammation as a common feature of many depression symptoms. I review 8 specific science-supported protocols for treating and avoiding depression, including EPA fatty acids (which have been shown to rival certain prescription treatments), how exercise protects against depression, studies of creatine, adjusting dopamine balance and more. I also discuss the results of ongoing clinical trials for ketamine and psilocybin for depression, how these compounds work and finally, I review how ketogenic diets can help in certain cases of depression, especially treatment-resistant major depression. 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) Mood Disorders & Maintaining Mental Health (Protocol 1) (00:07:25) Sponsors: AG1, LMNT (00:11:15) Major Depression (00:18:40) “Anti-Self” Confabulation (00:21:42) Autonomic (Vegetative) Symptoms of Depression (00:26:58) Norepinephrine, Dopamine & Serotonin (00:31:50) SSRIs (Prozac, Zoloft, etc.): Selective Serotonin Reuptake Inhibitors (00:37:00) Epinephrine/Motor Functions, Dopamine/Motivation & Craving, Serotonin/Emotions (00:39:33) Physical & Emotional Pain are Linked: Substance P (00:41:50) Hormones & Depression: Thyroid & Cortisol (00:46:50) Genetic Susceptibility to Depression: Impact of Stress (00:50:50) Understanding Biological Mechanism Is Key: Recipes versus Skills (00:52:50) Tools for Dealing with Depression: Logic & Implementation (Protocol 2) (00:56:25) Brain Inflammation & Mental State: Cytokines, Prostaglandins, etc. (00:59:20) Protocol 3: Essential Fatty Acids (Omega-3, EPAs: Eicosapentaenoic Acid)* (01:02:50) How EPAs Help Offset Depression: Serotonin Synthesis, Kynurenine, Quinolinic Acid (01:05:25) Protocol 4: How Exercise Offsets Depression (01:11:44) Protocol 5: Creatine Monohydrate, Forebrain Function & NMDA receptors* (01:20:30) Protocol 6*: Ketamine, PCP (*Prescription-Only), & NMDA-Receptor Function (01:33:08) Protocol 7*: Psychedelics (*In Clinical Trials) for Major Depression: Psilocybin* (01:47:00) Protocol 8: Ketogenic Diet, GABA (Gamma-Aminobutyric Acid) (01:54:50) Summary of Protocols Covered (02:00:10) Support & Additional Resources Title Card Photo Credit: Mike Blabac Disclaimer
Transcript
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Welcome to the Huberman Lab podcast where we discuss science and science-based tools for everyday life.
I'm Andrew Huberman and I'm a professor of neurobiology and ophthalmology at Stanford School of Medicine.
This month we're talking all about disorders of the mind.
Things like depression, attention deficit disorders, eating disorders, schizophrenia, and bipolar disorder.
During the course of this month, we are going to discuss the psychological and biological
underpinnings of mood disorders of all kinds.
You'll learn a lot of science.
You'll also learn a lot about the various treatments that exist and that are in development
for these various mood disorders.
We will talk about behavioral tools, things like exercise, meditation, breath work, but
also prescription drugs, supplements, and novel compounds that are now being tested in various
clinical trials.
Across the month, I think you'll start to realize that there are common pathways underlying
many mood disorders.
In fact, mood disorders that look quite different from one
and other often depend on the action of the same neurochemicals
or neural circuits in the brain and body.
That actually should be a point of great relief,
because what it means is that by understanding
the biology of one mood disorder or understanding
how one treatment or behavioral intervention
can impact a mood disorder, we gain insight
into other mood disorders as well. mood disorder, we gain insight into other
mood disorders as well.
As always, we will discuss science and science-related tools that people could implement should
they choose.
Before we dive into today's topic, I'd like to discuss a very particular set of scientific
findings that relate to today's topic and that are important for understanding all mood disorders and all
states of motivation, happiness, and sadness, as well as depression.
Basically I'm going to paraphrase a brief segment of my discussion with Dr. Anna Lemke,
who I sat down with to discuss addiction and the biological basis of addiction and addiction
treatment. A very important aspect of that discussion was when Dr. Lemke described the pleasure pain
balance.
Literally, the circuits in our brains that control our sense of pleasure and pain, and ultimately,
whether or not we remain happy in our pursuit of pleasure or not.
This is an absolutely crucial aspect to the way that we function in
everyday life and especially under conditions of mood disorders. The pathway
that she was describing is the so-called pleasure system. However, what most
people don't realize is that the pleasure system is also directly associated
with and in fact is the very same system that modulates mental or psychological
anguish and pain.
Essentially what she described
is that whenever we pursue something
that we think will bring us pleasure,
and that could be anything that we think
will bring us pleasure,
from food to video games to sex,
to a particular job or goal,
short term or long term,
that we experience release of the
neuromodulator dopamine. Now dopamine is associated with increased levels of
motivation and drive. It is not the molecule reward, it is the molecule of
craving, motivation and drive. However, as Dr. Lemke pointed out, when we are in
pursuit of something, there is a release of dopamine in our brain.
That makes us feel motivated and in general, it makes us feel good.
But very shortly thereafter, and beneath our conscious awareness, there is a tilt of the
pleasure pain balance in the brain, literally a shift in the neural circuits that underlie
pleasure and pain, such that every bit of pleasure or
pleasure seeking that causes release of dopamine will be balanced out by a little bit of pain.
And we don't experience this as physical pain, at least not at first.
We experience it as craving for more of the thing that brought us pleasure.
Now that sounds pretty good.
You get pleasure and then you get a little bit of pain to balance it out. It's subconscious and you experience it as the desire to seek out more
pleasure. However, it's actually more diabolical than that. And we really need to keep an eye on this
if we are to remain happy, if we are to remain in pursuit of our goals. The crucial thing to understand
is that if we remain in constant pursuit of pleasure,
the pain side of the balance tips so that each time we are in pursuit of that pleasurable thing activity or substance, we are going to experience, we literally achieve less dopamine release,
each subsequent time. So we get less pleasure and the amount of craving increases.
Now, after a certain point or threshold, we call that addiction and the amount of craving increases. Now, after a certain point
or threshold, we call that addiction and the way to reset the balance. This is very important.
The way to reset the balance is actually to enter into states in which we are not in pursuit
of pleasure. To literally enter states in which we are bored, maybe even a little bored and anxious,
and that resets the pleasure pain balance,
so that we can return to our pursuit of pleasure in a way that's healthy, and then in an ongoing
way, won't lead to this overtipping or this increase in the amount of pain or addiction.
So this is very important, and if this seemed vague, what this means is, we should always be cautious
of any state of mind or body or any pursuit
that leads to very large increases in dopamine.
And if it does, we should be very careful to not pursue that repeatedly over time.
During today's episode, I'm going to give an example, a real life example of a discussion
that I've been in with a young man who's 21 years old, who's dealing with a disruption
in this pleasure pain balance.
He is essentially depressed.
And he's depressed because of his ongoing pursuit of a particular activity that initially
led to a lot of dopamine, but over time has led to less and less dopamine and more and
more of this pain side of the balance.
We could call him addicted to that particular activity,
whether or not he's addicted by clinical standards
or not really isn't important.
What is important is that he experiences this
as depression, as low affect as it's called
or an hedonia, an inability to experience pleasure
from that thing or from anything else.
And he's currently undergoing treatment
through a rebalancing of this pleasure pain pathway.
So while I can't reveal his identity to you,
that wouldn't be appropriate.
He did give me permission to reveal
the general architecture of what he's coping with.
And I spent some hours with him on the phone this week,
talking to him as well as to the various people
that he's working with to really understand
what's going on here.
Because I think it can illustrate
the relationship between dopamine, pleasure, and pain
for sake of addiction, but also for understanding
how to avoid depressive states,
how to remove ourselves from depressive states.
And as you'll see today as we discuss depression,
many of the molecules and neural pathways
and biological mechanisms that we know can be used
to counter depression, feed back
onto this pleasure-pain balance.
Before we begin, I'd like to say that this podcast
is separate from my teaching and research roles at Stanford.
It is, however, part of my desire and effort
to bring zero cost to consumer information
about science and science-related tools
to the general public.
In keeping with that theme, I'd like to thank
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Today we're discussing depression.
In particular, we're gonna talk about major depression.
The phrase major depression is used to distinguish
one form of depression from the other, the other one being major depression. The phrase major depression is used to distinguish one form of
depression from the other, the other one being bipolar depression. Bipolar depression, sometimes
called bipolar disorder, is really characterized by manic highs, so where people aren't sleeping and
they're talking very fast and they're buying things and pursuing resources that they can't afford. They're starting relationships left and right.
They're manic.
Followed by periods of crashes of feeling very low, lethargic, and so on.
Bipolar depression is an absolutely crucial thing for us to discuss, and therefore we are
going to have an entire separate episode related to bipolar depression.
Today, we're going to talk about major depression episode related to bipolar depression.
Today we're going to talk about major depression, also sometimes called unipolar depression,
just because it doesn't have the highs and lows.
It's more characterized by the lows.
We're going to talk about the biology, the psychology, and the various treatments, behavioral
drugs, supplementation, diet, exercise, all of that.
Before we go forward into the material, I just want to emphasize that any discussion about
mood disorders carries with it a particular sensitivity.
And that sensitivity is one related to self-diagnosis.
Today's episode, and indeed in the future episodes for this month on mood disorders, you're
going to hear very symptomologies that are used to diagnose
and characterize these disorders. If you recognize some of these symptomologies in yourself or in
others that you know, that's an important thing to take note of. However, accurate diagnosis
really should be done by a qualified healthcare professional. So at once I'm saying, keep your
eyes in your ears up for things that sound familiar to you that might be of concern.
And at the same time I'm saying don't necessarily leap to conclusions. Take those flags of concern if they're there and bring them to a qualified healthcare professional and they'll be able to properly diagnose you as having a particular mood disorder or diagnose somebody as having a particular mood disorder or not.
And that's an essential step.
And I'll say this to protect us.
I say this really to protect you.
Okay, let's have a fact-based discussion about depression.
And I promise you that where we don't know
certain things about depression,
I will be clear to tell you.
In fact, we are going to talk about some treatments
for depression that are looking very promising and that right now are actually being used more and more. And
from my read of the mechanistic literature, we're still a bit in the dark as to how these
work. It's actually a common theme of medicine. Many times there are treatments that seem
promising or that look really terrific. And there isn't a lot of understanding about mechanism.
However, any good discussion about neuroscience,
and in particular about mood disorders,
has to get into mechanism.
So we're gonna do that, and in doing that,
we're gonna frame the discussion
for the tools of how to keep depression at bay
and how to deal with it if you happen
to find yourself depressed,
or if you know somebody else who's depressed.
What is this thing we call depression?
Was I mentioned before it has two forms by polar depression, which we're not talking
about today, and major depression, also called unipolar depression, is the other.
Major depression impacts 5% of the population.
That is an enormous number.
That means if you're in a class of 100 people,
five of them are dealing with major depression or have at some point. Look around you in any
environment and you can be sure that a good portion of the people that you're surrounded by
is impacted by depression or will be at some point. So this is something we really have to take seriously and that we want to understand.
It is the number four cause of disability. A lot of people miss work, miss school, and before then, likely perform poorly in work or school do to major depression. Now, there's a very serious challenge
in having a discussion about depression, and it relates directly to the challenges in diagnosing depression.
Earlier, I did an episode with Dr. Carl Diceroth, who is indeed a medical doctor and a PhD,
he's a psychiatrist, and he made a very important point, which is that the field of psychiatry
and psychology are confronted with a challenge, which is they're trying to understand what's going on within the stuff that's in our brains that's deep to our skulls. We don't have access to that without
brain imaging and electrodes and things like that. Someone just comes into the office and the
dissection tool for depression, so to speak, is language. In order to determine if somebody has
depression or not, we have to use language. How they talk about things, also how they carry their body, also some general patterns
of health.
So, let's talk about depression the way that clinicians talk about depression.
Because one of the issues is that we use the word depression loosely.
A lot of people say, oh, you know, I'm so depressed.
I didn't get this job or I'm so depressed.
I just, I don't know, I had a really rough week or I'm exhausted. I'm so depressed or I'm so depressed. I didn't get this job or I'm so depressed. I just, I don't know, I had a really rough week
or I'm exhausted.
I'm so depressed or I'm so depressed.
I thought I was gonna go on vacation
and then they canceled the flight.
Okay, that is not clinical depression.
That's called being bummed out, being sad or disappointed.
Now that person might be depressed,
but clinical depression actually has some very specific
criteria and those criteria are mainly characterized by the presence of certain things
and the absence of a few particular things.
So let's talk about the things that are present in somebody that has major depression.
First of all, there tends to be a lot of grief.
There tends to be a lot of grief. There tends to be a lot of sadness.
That's no surprise.
The threshold to cry is often a signature of depression.
Now that doesn't mean that if you cry easily, that you're depressed, some people cry more
easily than others.
But if you're somebody who typically didn't cry easily and suddenly you find yourself crying
very easily, that could be a sign of depression.
And I want to emphasize, could.
There's also this thing that we call an hedonia, a general lack of ability to enjoy things,
things that typically or previously we enjoyed,
things like food, things like sex, things like exercise,
things like social gatherings,
a kind of lack of enjoyment from those things.
Sometimes that lack of enjoyment is sad
and sometimes it's just flat.
It's just kind of neutral. It doesn't feel good because there's nothing there. It's like bland food.
It's like these experiences are analogous to biting into your favorite article of food and
it's just not tasting very good. It just doesn't taste like anything at all. And that's a common symptom of major depression. The other one is guilt. Oftentimes people with depression will feel very guilty about
things they have done in the past or they'll just generally feel badly about themselves. And we're
going to talk about this because it relates to some of the more serious symptomology seen in depression
sometimes, things like self-harm mutilation or even suicide.
But for the time being, we want to frame up and hedonia this lack of ability to achieve
or experience pleasure, a kind of a flat affect as it's called, sometimes even delusional
thinking, negative delusional thinking.
And in particular, anti-self-confabulation.
What is anti-self-confabulation. What is anti-self-confabulation?
Well, for, so what,
confabulation is an incredible aspect
of our mind and our nervous system.
You sometimes see other forms of confabulation
in people who have memory deficits,
either because they have brain damage
or they have age-related dementia.
A good example of this would be someone
with age-related dementia,
sometimes we'll find
themselves in a location in the house and not know how they got there.
And if you ask them, what are you doing here?
They will create these elaborate stories.
Oh, you know, I was thinking about going to the shopping today and I was going to take
the boss and then I was going to do.
They create these elaborate stories.
They confabulate.
And yet that person hasn't left the house in weeks, and that person doesn't have a driver's
license.
And so they're really just creating this stuff.
They're not lying to get out of anything.
They're confabulating.
It's as if a brain circuit that writes stories just starts generating content.
In major depression, there's often a state of delusional anti-self confabulation where
the confabulations are not directly
or completely linked to reality,
but they are ones that make the self,
the person describing them seem sick
or in some way not well.
A good example would be somebody
who experiences a physical injury, perhaps.
Maybe they break their ankle, maybe it's an athlete,
and they also happen to become
depressed.
And you'll talk to them, you say, how are things going, how's your rehab going?
Oh, it's okay.
And I don't know.
I'm just, I feel like I'm getting weaker and weaker by the day.
I'm just not performing well.
And then you'll talk to the person that they're working with, their kinesiologist or whoever
the physical therapist is, and they'll say, no, they're actually really improving.
And I tell them they're improving, but somehow they're not seeing that improvement.
They're not registering that improvement.
You notice that sometimes it's subtle,
and sometimes it's severe, but they'll start confabulating.
You'll say, actually, heard you're doing much better.
You're getting better.
You're taking multiple trips around the building now
before you could barely get out of bed,
and they'll say, yeah, well, basically,
they change some things about the parking lot that make it easier to move around.
So it's not really me.
And these aren't people that are just explaining away their accomplishments because they're
trying to brush off praise.
They are viewing themselves and they're confabulating according to a view that is very self-deprecating to the point where it doesn't match up with reality
It's not what other people see and it's actually not matched up with reality and that's a symptom of
Depression that I think we don't often think about or conceptualize enough
So it's not just telling people. Oh, yeah, you know, it's not as good as it seems everything's bad
These people really believe that and it becomes disconnected from reality.
So it's if they're sort of sinking into a pit and they're losing touch with the realities
of the world, including data about themselves, their ability to move and get around, for example,
in the particular instance that I used as an example, but there are others as well.
The other common symptomology of major depression is what they call vegetative symptoms.
Okay, so vegetative symptoms are symptoms that occur without any thinking, without any doing,
or without any confabulation. These are things that are related to our core physiology. The word
vegetative, you might know it sounds like vegetable, it actually relates to what a system in the body that nowadays is more commonly called the autonomic nervous system.
The
vegetative nervous system and the autonomic nervous system historically were considered sort of one in the same and it relates to things like the stress response or to our ability to sleep.
So vegetative symptoms be things like
constantly being exhausted. The person just feels exhausted.
It's not because they exercise too much.
It's not necessarily because of a life event.
It could be, but they're just worn out.
They don't have the energy they once had.
So it's not in their heads.
It's probably, and now I think we have good data
to support the fact that there's something off.
Something is disrupted in the autonomic or so-called vegetative nervous system.
One of the most common symptoms of people with major depression, one of the signs of major
depression, is early waking and not being able to fall back asleep despite being exhausted.
Waking up at 3am or 4am or 5am, just spontaneously and not being able to go back to sleep.
Now, I want to emphasize that that could happen for other reasons as well,
but it is a common symptom or warning sign of major depression.
So let's talk more about sleep and depression. It's well known that the architecture of sleep
is disrupted in depression. What's the architecture of sleep? I've done entire episodes about this, but very briefly in two sentences, although there probably be run on sentences.
Early in the night, you tend to have slow wave sleep more than REM sleep or rapid eye movement sleep. As the night goes on, you tend to have more rapid eye movement sleep.
That architecture of slow wave sleep preceding rapid eye movement sleep is radically disrupted
in major depression.
In addition, the pattern of activity in the brain
during particular phases of sleep is disrupted.
Now, this is during sleep, so this can't be that people
are creating this situation for themselves.
These are real physiological signs
that something is off in this so-called
autonomic or vegetative nervous system. And then there are some physiological signs that something is off in this so-called autonomic or vegetative
nervous system.
And then there are some other things that relate to the autonomic nervous system, but that
we normally think of as more voluntary in nature.
And these are things like decreased appetite.
So you could imagine that one could have decreased appetite because of the anhydonia, the lack
of pleasure from food, right?
If you don't enjoy food, then you might be less motivated to eat it.
That makes sense.
As well, because of these disruptions in the autonomic nervous system, these vegetative
symptoms, as they're called, you could imagine that someone would have decreased appetite
because some of the hormones associated with appetite, hypercretinorexin and things of
that sort, grellen, that those would be disrupted. And if those names of hypercretinorexin and gre of that sort, grellen, that those will be disrupted.
And if those names of hypercretinorexin and grellen
don't make any sense to you, don't worry about it.
What those are, just hormones that impact when we eat,
when we feel hungry, and when we crave food more,
as well as when we feel full.
We have enough so-called satiety.
If you want to learn more about those,
we did entire episodes on eating and metabolism.
So you can see that the symptomology of major depression impacts us at multiple levels.
There's the conscious level of how excited we are generally. Well, that's reduced. There's
grief. There's guilt. There's crying. But then there's also these vegetative things. There's
disruptions in sleep, which of course make everything more challenging when we're awake.
We know that sleep is so vital for resetting. You're waking up early. You can't get back to sleep. That's gonna
That's going to adjust your affect your emotions in negative ways. We know this and
Apatite is off and there are hormones that get disrupted. So cortisol levels are increased in particular
There's a signature pattern of depression whereby cortisol, this stress hormone that normally
is released in a healthy way only in the early part
of the day is shifted to late in the day.
In fact, a 9 p.m. peak in cortisol is one
of the physiological signatures of depressive-like states.
It's not the only one, but it is an important one.
So there are a lot of things going on in major depression. And by now you're probably thinking,
a goodness, this is dreadful, like there's all this terrible stuff. And indeed, it is terrible.
It is a terrible thing to find oneself in a mode where things feel sad, you feel guilty,
you're exhausted. And oftentimes there's also an association with the anxiety system.
So just because people are exhausted and lethargic
and they don't enjoy things,
doesn't necessarily mean that there's an absence of anxiety.
There can also be a lot of anxiety
about what's gonna happen to me.
Am I gonna be able to achieve my goals in life?
Will I ever get out of this state?
And so things really start to layer on
and as if this sounds depressing to you,
it is indeed depressing. This is really the place that many people find themselves state. And so things really start to layer on. And as if this sounds depressing to you,
it is indeed depressing. This is really the place that many people find themselves. And
it's a pit that they just don't know how to climb out of. So let's just take a few minutes
and talk about some of the underlying biology that creates this cloud or this constellation
of symptomology. I think that's really important to do because if we want to understand the various treatments,
how they work and why they work and how to implement them,
we have to understand some of the underlying biology.
So let's spend a few minutes talking about
the biology of depression, what's known, what's not known.
Because in doing that, I think you'll get a much clearer picture
about why certain tools work to relieve depression
and why others might not.
So one of the most important early findings in the search for a biological basis of depression
was this finding that there are drugs that relieve some of the symptoms of depression.
Those drugs generally fall into three major categories,
but the first set of ones that were discovered
were the so-called tricyclic antidepressants
and the MAO inhibitors, the monoamine oxidase inhibitors.
You don't need to understand that nomenclature,
but I'm going to give you a little bit of detail
so that if you want to understand it, you can.
Most of this work took place in the late 1950s and in the 1960s and continued well until
the 1980s when new classes of drugs were discovered.
And these tricyclic antidepressants and the MAO inhibitors largely worked by increasing
levels of norepinephrine in the brain, as well as in the body in some cases.
And they were discovered through a kind of odd set of circumstances.
We don't have time to go into all the history,
but suffice to say that they were discovered
because of the exploration for drugs that altered blood pressure.
Norepinephrine impacts blood pressure
and drugs that lower blood pressure, reduce levels of
Norepinephrine, and that in many cases was shown to lead to depression or depressive-like
symptoms.
And so these drugs, these tricyclic drugs and the MAO inhibitors actually increase Norepinephrine,
and frankly, they do quite a good job of relieving some, if not all of the symptoms of major
depression.
However, they carry with them many side effects.
Some of those side effects are side effects related to blood pressure itself by increasing
nor adrenaline, nor epinephrine as it's called.
You raise blood pressure.
That can be dangerous.
That can be uncomfortable.
But they also have a lot of other side effects.
The reason they have other side effects is because they impact systems in the brain and
in the body that impact things like libido, appetite, digestion, and others, and we'll
talk about each of those in sequence.
Okay, so the experience that clinicians had of observing some relief for depression with
the tricyclic antidepressants
and with MAO inhibitors was terrific, but there were all these side effects.
Side effects that people really did not like.
They didn't like these drugs at all.
A lot of people get dry mouth.
I mentioned the low libido.
They'd have sleep issues, appetite issues, weight gain.
They made some people so uncomfortable that they preferred not to take them even though
when they didn't take them, they had a worsening or a maintenance of their depressive symptoms.
A decade or so later, there was the discovery of the so-called pleasure pathways in the
brain.
These are pathways, literally groups of neurons, that reside in different locations in
the brain, but connect to one another, so it's a circuit. And when you stimulate these neurons with certain behaviors,
or with electrical stimulation in an experiment,
believe it or not, that's been done in both animals
and humans.
Animals and humans become very, very motivated
to get more stimulation of these pathways.
So this pleasure pathway, or these circuits for pleasure,
are very what we call reinforcing.
In fact, animals and humans will work hard
to get stimulation of these brain areas
even more than they will work to obtain sex, drugs,
or even if they are addicted to a particular drug
and they are in a state of withdrawal,
the ultimate state of craving.
If given a choice, a person or an animal will select to have stimulation of this pleasure pathway instead of the drug itself. And that is a major and significant finding. This pleasure pathway,
as it's sometimes called, involves areas like the nucleus accumbens and the ventral
tegmental area. These are areas of the brain that are rich
with neurons that make dopamine. And if you think to the
symptoms of depression of anhydonia, a lack of pleasure, a
lack of ability to experience pleasure, well, that was a
smoking gun that there's something wrong with the dopamine
pathway in depression. And indeed, that's the case. So it's
not just Norupinephrine, it's also the dopamine or pleasure pathway
is somehow disrupting.
And then in the 1980s,
there was the discovery of the so-called SSRIs.
Most people are now familiar with the SSRIs,
the selective serotonin reuptake inhibitors.
The SSRIs worked by distinct mechanisms
from the tricyclic antidepressants and the MAO inhibitors.
As their names suggest, SSRI, selective serotonin reuptake inhibitors, prevent serotonin from
being wiped up from the synapse after two neurons talked to one another.
What do I mean by that?
Well, here's some very basic neurobiology 101.
If you don't know any neurobiology, you're going to know some in about 15 seconds.
Neurons communicate with one another
by spitting out chemicals into the little gap between them.
The little gap between them is called the synapse,
or by the brits, the synapse.
Those chemicals bind to the neuron on the opposite side
and cause changes in the electrical activity
of that neuron on the other side
of the synapse.
Serotonin is one such neurotransmitter or more specifically, it's a neural modulator.
It can change the activity of large groups of neurons in very meaningful ways.
Selective serotonin reuptake inhibitor means when a person takes this drug, some of those
drugs include things like prozac or Zoloft, the
more typical names or more generic names or things like Fluoxetine.
When people take those, more serotonin hangs out in the synapse and is able to be taken
up by the neuron on the opposite side because of this selective reuptake inhibition.
It prevents the clearance of serotonin from the synapse, and thereby more serotonin can
have an effect.
So SSRIs don't increase the total amount of serotonin in the brain.
They change how effective the serotonin that's already in the brain is at changing the
activity of neurons, okay?
So they don't increase serotonin,
they increase the efficacy
or the function of serotonin
in the way that I just described.
So that was more than 15 seconds,
but now you understand how SSRIs work.
And I wouldn't be talking about SSRIs
if they didn't in fact work.
Yes, there are many problems with SSRIs.
They do carry certain side effects in many individuals.
Also about a third of people that take SSRIs don't derive any benefit.
It doesn't relieve their symptoms of depression.
However, for the other two thirds, there's often a relief of some, if not all, of the symptoms
of major depression.
The problem is the side effects that accompany those SSRIs.
And so these days SSRIs are a complicated topic.
It's sort of what I would call a barbed wire topic,
because we often hear about all the problems with them,
but these drugs also have saved a lot of lives.
They've also improved a lot of lives.
The issue is that they tend to have varying effects
on different individuals and sometimes varying effects over time
So they'll work for a while then they won't work for a while
There are also a lot of mysteries about the SSRIs and those mysteries bother people what mysteries am I referring to?
Well SSRIs
Increase the amount of serotonin or more specifically they increase the efficacy of serotonin at the synapse
More specifically, they increase the efficacy of serotonin at the synapse. That happens immediately, or very soon after people start taking SSRIs, but people generally
don't start experiencing any relief from their symptoms of depression if they're going
to experience them at all until about two weeks after they start taking these drugs.
So there's something going on there that's not clear.
One idea is that the SSRIs actually can improve symptoms of
depression or even remove symptoms of depression through so-called neuroplasticity by changing the
way that neural circuits function. And there are many studies on this, but the main categories of
studies on SSRIs that relate to neuroplasticity fall into two camps. One is that the ways in which SSRIs might,
and I want to emphasize might,
be able to trigger the production of more neurons
in the brain, in particular areas of the hippocampus
called the dentate gyros and others,
that impact memory.
This is important, we're gonna come back to memory.
The other is that the SSRIs have been shown
in various scientific studies to reopen critical
periods of plasticity.
I'll just briefly describe one of those studies.
It was a study done by Lumberto Mfez group in Pisa that explored brain plasticity that's
known to be present in young animals and disappear in older animals.
This is also true in humans.
Younger humans have a far more plastic brain.
It can change in many more ways more easily than can the older brain.
What they showed was that fluoxetine prozac, given to adult animals, can reopen this incredible
period of plasticity, can allow more plasticity to occur.
I was interesting.
It's purely through increases in serotonin transmission.
And there are other studies showing that fluoxetine can increase the number of new neurons that
are born into the adult brain, so-called neurogenesis, the production of new neurons.
So it's very clear that there are at least three major chemical systems in the brain,
nor epinephrine dopamine and serotonin that relate to and can adjust the symptoms of
depression.
And those actually can be divided into separate categories.
So for instance, epinephrine, or norapinephrine is thought to relate to the so-called psychomotor
defects, sometimes called psychomotor retardation.
This is the lethargy.
This is the exhaustion.
This is the inability to get out of bed in the morning.
Dopamine is thought to relate to the anhydonia,
or I should say lack of dopamine in depressive patients.
It's thought to lead to the anhydonia,
the lack of ability to experience pleasure.
And serotonin is thought to relate to the grief, the guilt,
some of the more cognitive
or more emotional aspects of depression.
So we've got the norepinephrine system related to activity and alertness, the dopamine system
relating to motivation, pleasure, and the ability to seek and experience pleasure, and then
the serotonin system that's related to grief.
And unfortunately, brains and organisms don't work in a simple
mathematical way where you just say, oh, well, this person's experiencing a lot of grief,
but they don't have any problems with, you know, lethargy. And so let's just boost up their
serotonin. On paper, it works, but oftentimes it doesn't work clinically. And another
patient, you might get somebody who can't experience pleasure, but they're kind of anxious.
They don't have any trouble sleeping, but they're just much more anxious and frustrated than
they normally are, and they meet the symptoms of depression.
Well, you might think, oh, well, you just give that person some drug to increase dopamine,
and everything will be better.
And indeed, in some cases, that's true.
There are drugs like well-butrin, which function more specifically on the dopamine
system to increase dopamine, and they also increase norapinephrine. Many people get great
relief from things like well butrin. They don't really impact the serotonin system so much,
and therefore you don't get a lot of the serotonergic or serotonin related side effects.
However, some people feel far too anxious on those drugs. Some people get addicted to those drugs in a way
because a lot of those drugs that increased open
me make you want more of those drugs.
So you start to realize that what makes sense on paper
doesn't always make sense clinically.
And this is why it's complicated
and a really good psychologist and really good psychiatrist
will work with someone to try and pull and push
on these various systems to find the combination of drugs
that maybe or may not be correct for them.
There's a fourth aspect of the chemistry of depression that's really important to understand,
and that's pain.
We've talked about pain on this podcast before, but even if you didn't hear the episode
on pleasure and pain, I just want to emphasize that pain is something that we experience
in our body, no surprise there, an injury, a cot, et cetera,
but that we also experience emotional pain,
and those systems are linked in very intricate ways.
There's actually some data showing that pain relievers,
Tylenol, aspirin, these sorts of things,
can help certain people with emotional pain.
Now, I'm not recommending people run out
and take those things for emotional pain,
but actually, if you think about that,
shouldn't come as any surprise given the enormous number
of people that take pain killers, opioids, and things like them to try and relieve their
psychological pain.
And as we know, those drugs are very, very problematic for many individuals.
They can help certain individuals, but they are very prone to abuse and they can induce
addiction very easily in a number of people.
There's a substance that's literally called substance P, the letter P, that's manufactured
by neurons in our brain and body, which underlies our sensation of pain.
And indeed, substance P inhibitors have been used to treat depression, and in some cases
works.
A lot of people with depression are hypersensitive to pain.
And of course, they could have multiple things going on.
They could have chronic pain or chronic injury
and major depression.
So you start to get the constellation
of the many things that could happen.
So that's all I wanna say today about the chemistry
underlying depression or major depression.
There's a lot more there,
but I think if you understand the Neuroepinephyron system
and that it relates to some of these things like lethargy, the psychomotor defects, as they're called
dopamine and how it relates to motivation and lack of motivation and lack of dopamine and depression
and serotonin and its relationship to grief and that low serotonin can lead to extreme grief and
shame and higher serotonin levels can sometimes restore a sense
of well-being and safety and feeling good about oneself.
If you understand that and you understand that physical pain
is somehow involved in certain cases,
I think you will know more about depression
and its underlying chemistry than most all people out there.
And if you'd like to learn more,
I invite you to pursue searching those terms
further on the internet
and we'll certainly go into them in more depth, but that really sets the stage for where we're headed next.
So next I'd like to talk about hormones and how they relate to depression.
And I'd also like to talk about stress and how it relates to depression, as well as talk about some of the genetics or the predispositions to depression.
And for those of you there are thinking, hey, I want the tools, I want to know how to fix depression.
I understand the desire for that.
I will just ask if you hang in here with me a little bit longer,
not only will you learn a lot more about how this
complicated mood disorder works.
Some of the more interesting things about it,
but it will also position you to get a lot more out
of the tools that we will describe.
You always have the option to skip forward, of course, but I think it's important to understand
some of the hormonal and stress-related aspects of depression.
So, let's talk about hormones.
20% of people that have major depression have low thyroid hormone.
Thyroid hormone is related to metabolism.
Oftentimes, we think about thyroid as only related to,
you know, having a fast metabolism.
But thyroid is related to all forms of metabolism,
including our ability to synthesize new tissues
like protein and repair injuries.
I did a whole episode on thyroid and growth hormone.
If you wanna check that out,
all of that is archived at hubermanlab.com,
it's all timestamped, et cetera.
You can find on YouTube, Apple Apple Spotify, all those places.
So if you're curious about thyroid hormone
and growth hormone, and you want to do the deep dive
on those, and you want to learn how to alter their levels,
using various approaches, check that out.
But 20% of people with major depression are hypothyroidal.
They don't make enough thyroid.
And that leads to low energy, low metabolism
in the brain and body. And there's a condition called Hashimoto's, which is essentially
low thyroid output. And again, I don't want to get into all the tools related to thyroid.
Sometimes a psychiatrist will prescribe thyroid medication to increase thyroid output in
people that are depressed. And that will work to relieve the symptoms. So, there isn't necessarily a direct problem with serotonin dopamine and orapinephrine,
or substance-p.
Sometimes it's a thyroid problem.
So, there are certain situations or conditions that can impact the thyroid hormone system,
and make people more susceptible to depression or make a pre-existing depression worse.
And those are things like childbirth.
So, it's well known that women who give birth
can often undergo what's called postpartum depression.
It actually comes from the word postpartuition depression.
They give birth, what's happier, what's more joyful
than the birth of a new healthy child
and they will lapse into a depression
and that's thought to be hormonally related.
Either directly to the thyroid system or perhaps to the cortisol system as well.
We'll talk about cortisol in a moment.
As well, certain women during certain phases of their menstrual cycle experience symptoms
that are very much like clinical depression and oftentimes are diagnosed with clinical
depression appropriately.
And of course, the menstrual cycle is associated with shifts in hormone levels.
As well, menopausin and postmenopausal women
are more susceptible to major depression,
regardless of whether or not they've had
that major depression earlier in their life.
So these are things to be on the lookout for
and to definitely talk to a doctor and get a blood panel
that hopefully includes measures of thyroid hormone
and cortisol hormone.
Why cortisol hormone?
Well, more stress is correlated with more
bouts of major depression across the lifespan.
How many bouts?
Well, it turns out that as you go from having one to two
to three, well, when you hit four to five bouts
of really intense to stressful episodes in life,
these tend to be long term stressful episodes,
your risk for major depression
goes way up.
So whether or not you have a genetic predisposition to depression or not, one of the best things
you can do to try and avoid getting depressed is to learn to control your stress system,
to not go from short-term stress, which everybody experiences.
We all have short-term stressors, to To medium term stress, to long term stress,
and to not have too many bouts of long term stress because that probability of getting depressed
goes way, way up. And this is something I've seen over and over again, not just in my scientific
career, but just throughout life, people in all sorts of domains, young and old. I've seen that
people will go through a very intense relationship, that break up, sometimes it's the staying together,
that's stressful, sometimes it's a graduate school
that can be stressful, sometimes it's some other event,
and then some months later, they become depressed.
And that's because the stress system is associated
with the release of cortisol.
The cortisol system can dramatically impact the way
that these different neuromodulators
dopamine, neuroponiferent, and serotonin function. And so there's this kind of late nor longer
lasting impact on the systems that impact mood and well-being. So learning how to control
your stress is really key if you're not depressed or you're somebody that has not lapsed into
a depression recently, take control of your stress system. And we did an entire episode on how to conquer stress,
and that involves dealing with stress in the short term,
the medium term, and in the long term.
And there are a lot of different ways to do that.
One of the more important reasons for learning
how to counter stress in order to offset depression
is that there is a genetic predisposition
that certain people carry to become depressed.
There are these studies now of many, many thousands of individuals.
These were mainly done in New Zealand, but these studies have now been done elsewhere, looking
at many tens of thousands of individuals who carry particular copies of genes, what they
are called polymorphisms, in particular of a gene called 5httlpr, which is a serotonin transporter.
So this is a gene that controls or regulates how much serotonin is available in the brain.
If you have this gene, this polymorphism, it doesn't necessarily mean that you will be depressed,
but it greatly shifts your susceptibility to depression under conditions of stress.
So, I realize some people are listening to this and some people are watching it on YouTube.
So, I'm going to describe this in a way that doesn't require looking at any graphs.
What I want you to imagine is a very shallow hill, like a very mellow hill.
It's just a ramp set at about 10 or 15 degrees.
Okay. 10 or 15 degrees. What we're plotting there in your mind is that with each bout of serious stress, so that
could be trying to finish a degree or a relationship break up or a family member that's sick or
the loss of a loved one or a pet, with each bout of stress, the probability that you will
experience a major depression goes up. However, if you carry this gene, this HTT LPR gene, the steepness of that curve goes way,
way up, or it's actually more like a line, such that you need far fewer bouts of stress
in order to lapse into a major depression.
Okay?
So if the typical person who doesn't carry this polymorphism
has to experience two or three or four or five bouts of stress before they lapse into a depression,
somebody with this gene is susceptible to getting depression after just one bout or two bouts of
intense stress. Okay? So that's how these genes work. They don't pre-ordain or determine you to be depressed. They raise
a susceptibility. And many genes, many things related to heritability in general work in
that way. And we know there's a strong genetic component to depression. How do we know?
Well, in what are called concordant monosigotic twins. So these would be identical twins. And they can either be in one biological sack or two biological sacks while in utero.
What's called monocorionic or dichorionic? Well, typically it's monocorionic and identical twins for which one of those twins goes on to have major depression.
There's a 50% probability that the other one will have major depression. So it's not 100%. It's not 100% inherited. It's not 100% genetic, as you might
say, but there's a much higher predisposition for depression. Whereas in fraternal twins,
that number drops and in siblings, that number drops to about 25% and in half siblings,
it's about 10%.
The number's vary from study to study,
but basically the more closely related you are
to somebody who has major depression,
the more likely it is that you will also get major depression.
And therefore, if you haven't gotten major depression,
the more likely it is that you should take steps
to learn to mitigate stress
because stress is the major factor
that can trigger one of these depressive episodes.
Okay, so we've covered a lot related to the stress
and the hormones and the neurochemistry of depression.
In fact, I think this is probably the deepest
I've ever gone into the biology of any topic
on this podcast before getting to any specific tools.
I mentioned that learning how to mitigate stress and deal with stress, learning how to
measure and adjust your thyroid hormone, those might be useful.
But next, I'd like to turn to some very specific tools that people who both have depression
or who are prone to depression, as well as people who don't have depression and simply want to
maintain a good mood, who want to maintain a positive affect and pursuit of things in life.
What are the things that you can do?
Turns out there are things that you can do,
and all of the biology that underlies
the utility of those things,
meaning the reasons those things work
will now make sense to you,
because they adjust things like serotonin and dopamine,
and they adjust them through very specific pathways.
I know for many people learning about mechanism is kind of grueling.
I realize this podcast isn't necessarily one that you can listen to passively while doing
other things, although I would hope that you could do that and still enjoy it and extract
the information.
Why mechanism?
Mechanism is so key because mechanism is a little bit like understanding some of the chemistry
of cooking.
If you read a recipe and you can follow a recipe, you often hear people say, I can follow a recipe,
that means that if you have every ingredient in that recipe, you're good.
You likely can make that dish, you can make that meal.
However, if you understand a little bit of the chemistry of why salt
has to be added third
and not first, or why the heat has to be adjusted at a particular time, well then not only
can you follow a recipe, but that also gives you flexibility for when salt isn't available
or when you want to adjust the flavor of the dish or when you want to try a new dish or
you want to get experimental.
So when you understand mechanism, it puts you in a tremendous place of power
to work with your system.
So it's not just plug and chug.
Like take 12 milligrams of this,
you either feel better or you don't.
You can really start to understand
how prescription drugs, supplements,
nutrition, behavioral tools,
how those things weave together
to either work for you or not work for you,
and get you to paths of healthy mind and body.
So let's think about why any tool would work to relieve depression.
We talked about how some of the drugs that impact these different chemical systems might
work and why they create some of the problems they create.
Problems are mainly created by the fact that they impact lots of systems in the brain and
bodies, so you take a drug to increase serotonin, but that serotonin is also related
not just to mood, but to things related to libido and appetite, and so you start disrupting
multiple systems.
The same could be said for behavioral tools, right?
That any behavioral tool that adjusts the levels of a particular chemical ought to perhaps provide some relief for some of the symptoms of major depression.
Let's take an example that I've talked about before on the podcast,
which is if you get into a very cold shower or you take an ice bath,
you will release nor up an effron in an epinephrine in your brain and body.
There's no question about that.
I don't think anyone can really escape that.
It's a kind of universal response to
being in cold water. Well, if some aspects of depression are related to low levels of
norapunephrine, we'll take in cold showers, relieve your depression. Perhaps it might
even relieve certain aspects of that depression. Is it a cure? Well, that's going to depend
on the individual. Will exercise help? Well, if you go out for a run, you're going to increase the amount of norepinephrine in
your body.
If you enjoy that run, it's likely that you'll increase the levels of dopamine and probably
serotonin in your brain and body as well.
Well, that cures your depression.
Well, there are a lot of studies exploring how exercise can impact depression and indeed regular exercise is known to be a
protective behavior against depression, but it also can help relieve some of the
symptoms of depression. So you may ask yourself, why would you need drugs at all?
Why would there be prescription drugs or the need for supplementation or other
things to alleviate the symptoms of depression? Ah, well that's the diabolical nature of depression,
which is if people are far enough along in this thing, this sometimes called disease, sometimes
called disorder, but major depression, oftentimes they can't get the energy to even get up and take
a bath or a shower. They have no motivation to do it. They have no desire to go for a run.
So you say, come on, let's go, you'll feel better.
I know you'll feel better.
It generates all these chemicals.
I heard on the whatever podcast,
you remember that podcast or another podcast
that getting into action does all these things
and they just don't want to do it.
And to you, a person who's not experiencing depression,
that perhaps could just seem like the most frustrating
and confusing thing in the world.
But it's very important to highlight the fact that these circuits that are accessible to some of us,
the circuits for happiness, for pursuit of pleasure, for exercise, for
getting in a cold shower if that's your thing, that those circuits are present in all people,
but for certain people that are experiencing major depression and are really in the depths of their depression, they can't really access those circuits in the same way
that people who are not suffering from depression can.
I hope that makes it clear.
It's not offering any excuses for them.
And indeed, I think those behaviors would help jolt them out of some of the symptomology
of depression, but they're just not accessible
to everybody.
So let's talk about the things that people can do to deal with depression.
And again, anytime you add a behavior or a tool or a supplement or subtract a behavior
or tool supplement, drug, et cetera, you absolutely should talk to your physician, especially
if you're somebody that's dealing with major depression.
I wanna focus on the stress system,
and I'm not just gonna tell you to get sunlight
in your eyes and to get a good night's sleep,
although I think everybody should do that
on a regular basis, ideally every day.
Talked about those ad nauseam on this podcast.
They will help your sleep.
They will help you alleviate stress.
I think you should have tools to deal with stress
in real time, et cetera. But let's look at depression from the standpoint of a deeper biological
phenomenon, which is inflammation and the immune system. There's growing evidence now
that many forms of major depression, if not all of them, relate to excessive inflammation.
Now, inflammation plays an important role in wound healing. Is it, it is a positive aspect of our immune system, our ability to combat wounds, combat
illnesses, et cetera, but inflammation gone unchecked, inflammation that lasts too long,
or is a too high amplitude, meaning too many anti-inflammatory or inflammatory cytokines
and things of that sort in the body is bad.
And there's decent evidence now that inflammation can lead to or exacerbate depression and
that if we want to control depression or limit or eliminate depression, that focusing
on reducing inflammation and its associated pathways is a really good thing to do.
And I think this is a really good thing
for everybody to do, regardless of whether or not
you suffer from depression or not.
And today we're gonna talk about exactly
how depression comes about through the inflammation pathway.
Okay, so first of all,
who are the major players in creating
chronic inflammation in the brain and body?
They are the inflammatory cytokines,
things like IL-6, interleukin-6,
things like tumor necrosis alpha, TNF alpha,
things like C reactive protein, all right?
Not all of these are cytokons, you have interferons
and you prostaglandins and a lot of these things,
but when we are stressed, chronically stressed,
we get inflamed. Our brain and various
locations in the brain become inflamed because certain classes of cells, in particular those
glial cells, the cells that are typically thought to just be support cells, those cells, and
their biochemistry and their dialogue with the neurons of the brain embody, starts to become
disrupted. I may have mentioned it earlier, I don't recall, but I certainly mentioned it in an earlier
podcast that adrenaline, epinephrine, when it's released in the body, it doesn't cross
the blood brain barrier, but there are certain things that are able to cross the blood brain
barrier when we are stressed, things like the E2 prostaglandins, those cross the blood
brain barrier, and our blood and our brain, therefore our brain and our body can communicate because certain things
can pass through this barrier we call the BBB
or the blood brain barrier.
And also we have something called the glimphatic system,
which is really a plumbing system
that links the brain and body.
It's the link between the immune system and the brain.
Well, there is a set of actions that we can take
in order to limit inflammation.
And this has been shown in several quality peer reviewed studies now to reduce inflammation
and to relieve some, and in some cases, all of the symptoms of major depression.
One of those approaches is to increase our intake of so-called EPA's or essential fatty
acids.
There's now a very long list of papers
and quality peer-review journals showing
that when people ingest a certain level of EPA omega-3 fatty
acids, the relief from depressive symptoms matches the SSRIs.
That's incredible, right?
That essential fatty acids could relieve symptoms
of depression as well as some of the prescription
antidepressants.
Now this doesn't necessarily mean you run off
and stop taking your antidepressants
if you've been prescribed them.
Please don't do that.
Please talk to your physician.
And I should mention that some of the same studies
have shown that increasing our intake
of these essential fatty acids,
in particular the EPA variety of omega-3s, can lower the effective dose of things like SSRIs,
meaning if we required a 50 milligram or 40 milligram dose of fluoxetine, that one can get by on a lower dose,
and thereby perhaps not experience as many
or as severe side effects by taking or supplementing with EPA's.
Now the threshold level seems to be about 1 gram, a thousand milligrams of EPA.
So you will sometimes see on a bottle of krill oil or fish oil or any other source, even plant source or other source of EPA,
that it's 1,000 milligrams or 1,200 milligrams.
But what's really important to look at is
whether or not there's more than 1,000 milligrams of EPA,
because the EPA in particular is what's important here.
And actually, in exploring some of the literature
on the effects of EPA is on cardiovascular health, excuse me, as well as their effects on
depression, there's some interesting dose-dependent responses, such that people who took anywhere from 400 milligrams to
5,000 milligrams of EPA's
achieved a variety of different benefits and in some cases some side effects will talk about those and
it does seem that this thousand milligrams
is the critical threshold for benefiting
or getting some relief from depressive symptoms.
But people who took two grams seem to do better.
And in the cardiovascular health realm,
there it's a little more complicated.
Some studies point to a very positive effect
on cardiovascular health by taking increasing amounts
of EPA, others not so much.
The current data point to the fact
that for every gram of EPA that won in jest,
there's about a 9% improvement in cardiovascular health.
The same dose dependent improvement
on psychological health, on incompatible depression,
can't really be stated.
I wouldn't say that the more EPA you take, the better you're going to feel.
So to speak, I don't think the data is a point to that.
However, it does seem that if you take a gram, a thousand milligrams or two thousand milligrams
of EPA, there does seem to be some substantial relief for many people, which emphasized many,
not all, for many people in major
depressive symptoms.
So how would this work?
Well it turns out that these inflammatory cytokines, they impact neurons and the circuits
of the brain that relate to things like serotonin dopamine and norepinephrine.
These inflammatory cytokines act in a variety of different ways, but they mainly act to inhibit
the release of serotonin noripinephrine endopamin, or the synthesis of serotonin noripinephrine
endopamin.
I'll give you one example of how EPAs can positively impact this process, and then it
points to a second tool, which is the proper utilization of exercise to offset the effects of depression.
So now you should understand why having healthy levels of serotonin is important for
maintaining healthy mood. It's not responsible for all the aspects of having a healthy mood.
There's also dopamine and norepinephrine, but it is a very important one. Dopamine, also called 5HT, essentially derives from a precursor called tripdaphan.
Tripdaphan arrives into our system through our diet.
Tripdaphan is an amino acid.
Tripdaphan is found in Turkey, it's found in carbohydrates, and that should therefore
raise the idea.
I wonder if one of the reasons why people who are depressed have such an appetite for
carbohydrate-laden foods is because they're trying to get more trip-to-fan and therefore more
serotonin.
And indeed, that's the case.
Trip-to-fan is eventually converted into serotonin.
However, if there's excessive amounts of inflammation, these inflammatory cytokines
cause tryptophan to not be converted so much into serotonin, but to be diverted down a different pathway.
The pathway involves something called IDO, in dolomine, which converts tryptophan into
chyneurine. Okay? Chyneurine actually acts as a neurotoxin by way of converting
into something called quinolinic acid. And quinolinic acid is pro-depressive. So if that seems
like a complicated biochemical pathway, what's basically happening here is that the triptophan
that normally would be made into serotonin, under conditions of inflammation is being diverted into a neurotoxic pathway.
An ingestion of EPA's because it limits these inflammatory cytokines, things like IL-6,
C-reactive protein, etc., can cause more of the tryptophan that one ingests or has in
their body to be diverted towards the serotonergic pathway.
Exercise it turns out also has a positive effect on the triptophane to serotonin conversion
pathway.
And the way it does it is really interesting.
You now know that triptophane can either be converted into serotonin or it can be converted
into this neurotoxin, which is a bad thing.
Exercise, the activation of the muscles through rhythmic repeated use, in particular, a
Robic exercise, but also resistance training has been shown to do this to some extent,
tends to sequester or shuttle the canuring into the muscle so that it isn't converted
into this neurotoxin that is pro-depression.
Okay, there are a lot of steps in the pathway
leading to depression.
But what this essentially means is that hitting
a certain threshold level of EPA intake,
whether by supplementation with fish oil or krill oil,
or through some plant source,
if you're not into ingesting fish or krill,
or trying to get up above that thousand milligram threshold
for EPA by ingesting particular food sources.
You certainly can do it through food.
You don't have to supplement,
but it's easier to do with supplements.
That doing that will limit the inflammation
that diverts trip-to-fan into this neurotoxic pathway
and exercise as well augments this conversion
of trip-to-fan into serotonin
because it takes this thing that would potentially be
a neurotoxin and it sequesters it, it pulls it away
so that it can't actually go have its pro-depressive effects.
So you've got multiple steps here.
You're describing two tools, increasing EPA
and regular exercise as a way of increasing serotonin
somewhat indirectly, right?
It's by limiting this bad pathway to promote the activity of a good pathway.
But from the data that are published in Quality Peer Review journals, it really appears
that this inflammation pathway does function to increase depression through these pathways.
And so knowing that there are behavioral steps and supplementation-based steps, or if
you prefer getting your EPA's from typical food,
from nutritional approaches,
I find that very reassuring that the mechanisms
all converge on a common pathway, serotonin.
That gives me great peace of mind
that when people say, hey, go out for a run
or you should get outdoors, exercise,
or you should take fish oil,
or like the Scandinavians do, exercise, or, you know, you should take fish oil or like the skin and aviants do. I have skin and avian family members. And
they are known to, or I should say they are quite open about the fact that during the winter
months in particular when depression is more likely, but throughout the year, really, they
make an effort to regularly ingest high levels of EPA, either through ingesting fatty fish and its skin.
I'm not a particular fan of ingesting the skin of fatty fish, or by supplementing with
cod liver oil or other types of fish oil, sardines and things of that sort, sardine oils.
There are a number of different things out there that one could use.
So I find it very reassuring that there's a common biochemical pathway that can explain
why these things not just work, but why they should work. They should work because they operate in the very same biochemical pathways
that antidepressants that are prescribed to people do. So what does this mean for you? Well,
if you're somebody who suffers from major depression, again, don't stop taking your prescribed
medication, talk to your doctor, but talk to them perhaps about the EPA's
and exercise and how these things can impinge on the same biochemical pathways.
If you're somebody who's not suffering from major depression, I still think these pathways
are really important to understand.
And actually knowing these pathways is additional motivation to get regular exercise.
I think we all know that we should be getting anywhere from 150 minutes to 180 minutes per week of so-called zone two cardio for cardiovascular effects. Zone two is the kind
of mellow-ish cardio where you can sort of hold a conversation if you needed to, but it's a little
bit tough. You're kind of sucking for air a little bit. And that's going to limit these depressive
like symptoms. I think in all of us, I don't think that we should think of depression as a strict threshold. I'm somebody who personally has made the choice to take a thousand milligrams of EPA per day.
I do that by supplementing fish oil.
There's debate out there as to whether or not it's better to take EPA and DHA in particular
ratios and whether or not DHA can impact the LDL, which is the so-called bad cholesterol, that's
getting really down into the weeds, and we can talk about that in a future episode.
But for myself, I notice a pretty substantial positive effect of taking anywhere from
a thousand milligrams to two thousand milligrams of EPA per day.
I do that through supplementation, and I do strive to try and eat some fish, even though,
frankly, I've never liked the taste of fish. For those of you that would like a little more detail
or perhaps a lot more detail into the effects of EPA
on depression and in relieving depressive symptoms,
and if you wanna get into the nitty gritty of it,
I invite you to go to examine.com,
put in depression, EPA, they list off
and have links to 28 studies on the effects of EPA on major depression.
If you go to PubMed, there are many, many studies on this now that date back several decades
really.
If you're interested in the specific effects of EPA as opposed to DHA, I want to point
you towards a particular study entitled, not surprisingly, EPA, but not DHA, I want to point you towards a particular study entitled, not surprisingly, EPA, but
not DHA, appears to be responsible for the efficacy of omega-3 long chain polyunsaturated
fatty acid supplementation and depression, evidence from a meta-analysis of randomized
control trials.
This is a really wonderful paper.
The author is Julian Martens, M-A-R-T-I-N-S. It was published in 2009.
We will provide a link to this study in the caption.
That study is really the one that, at least to me, points to why EPA in particular is what's
effective and that whether or not DHA is problematic or not is a separate issue, but it's really
the EPA that one wants to hit a certain threshold level of if one's
goal is to get relief from depression or to keep depression at bay by keeping mood elevated,
which is why I take a high dose EPA.
So we've got EPA, we've got exercise, now you understand how they work to adjust mood.
Now I want to talk about something that at at least for me, was quite surprising when I first
learned about it for sake of treatment of mood disorders.
And that's creatine.
Creatine has a number of very important functions throughout the body.
For those of you that are into resistance training, and actually for those of you that are into
endurance training as well, creatine has achieved a lot of popularity in recent years
because supplementation with creatine can draw more water
into muscles and can increase power output from muscles.
So it's something that does indeed work.
There have been debates about whether or not it's unhealthy
for the kidneys to take long-term creatine supplementation
at high doses.
And I invite you to go down that rabbit hole.
I think most people now accept the idea that for most people, not all, but for most people,
low-dose creatine supplementation of anywhere from one gram to five grams per day can have
a number of positive effects on physical performance.
People with kidney issues, et cetera need to be especially cautious, but
creatine is interesting for that purpose. However, there's also a so-called phosphocreatine
system in the brain, and that phosphocreatine system has everything to do with the dialogue
between neurons and these other cell types called glia, and glia comprise, you know, several
cell types, microglia, astrocytes, et cetera. But the phosphocreatine system in the four brain in particular,
in the front of our brain, has been shown to be involved
in regulation of mood and some of the reward pathways,
as well as in depression.
And there are now several studies, at least three,
although they're probably more by time this comes out because they're
coming out very quickly now, at least three quality studies pointing to the fact that
creatine supplementation doesn't just have these positive effects on physical performance
but can also be used as a way to increase mood and to improve the symptoms of major depression. This has been now done in
several double-blind placebo controlled studies.
These studies have looked at women, have it looked at men, have looked at adolescents,
some of whom were taking SSRIs, some of whom were not. They've done
magnetic resonance spectroscopy.
So spectroscopy is a way that you can look at the concentrations of particular compounds
in the brain in real time, in humans.
It can be used for other things as well, of course.
And basically, what's been observed is that increasing the activity, the phosphocreatine
system in the forebrain can be beneficial or at least is correlated with improvements in mood.
So let's just talk for a moment about what's involved with using or supplementing creatine
in order to improve mood and perhaps even treat depression.
First of all, when I talk about creatine, I'm talking about creatine monohydrate.
There are a number of different forms of creatine.
Here I'm talking about creatine monohydrate. There are a number of different forms of creatine. Here I'm talking about creatine monohydrate.
The American Journal of Psychiatry in 2012
published a study which was a randomized
double blind placebo controlled trial
of oral creatine monohydrate.
And what it found is that it could augment
or enhance the response to a selective serotonin
reuptake inhibitor, in particular in women
with major depressive disorder.
So like EPA, creatine supplementation
seems to either lower the required dose of SSRI
that's required to treat depression
or can improve the effectiveness of a given dose of SSRI.
However, there are other studies that have looked directly at
creatine supplementation in the absence of SSRIs, and those are interesting as
well. There's a wonderful and very comprehensive review on creatine for the
treatment of major depression that includes beautiful tables of all the
subjects and the dosages, etc. I'm not going to read off every line and every column in that review, but we will provide a link to that review as well.
One of the things that's really striking about the list of studies that they include is that most of them used dosages that are pretty reasonable for most people, anywhere from three grams to five grams, sometimes up to as many 10 grams per
day of creatine. Many of these also were shown to increase activity of this phosphocreatine
system in the forebrain. And some show a relationship between that phosphocreatine system and
a particular category of receptors in the brain called the
NNM, excuse me, DA receptor, N-methyl-D-aspertate receptor.
The NMDA receptor is one of the first things that every budding neuroscientist learns about
because it is the receptor that has particular electrical and chemical properties that make
it a critical gate for
so-called neuroplasticity.
So it's not a receptor that's activated in the brain, typically for just the functioning
of the brain on a day-to-day basis.
It's a receptor that's activated when circuits are going to change, when they are inspired
to change by some very strong stimulus,
meaning some experience, or in some cases a drug, or in some cases something else.
But the NMDA receptor is a kind of a key node for shifting brain circuitry.
And so while the details aren't entirely clear, it seems that creatine supplementation
leads to increases in the phosphocreatine system
in the forebrain, and that increases in the activity of the forebrain phosphocreatine
system relate to changes in the way the NMDA receptors function and may lead to some of
the plasticity, the changes in neural circuits that underlie the shift from negative mood
and affect to positive mood.
Now, there are a lot of gaps.
Those are, you know, there are a lot of little boxes or bins in the diagram I just laid out
for you.
And some of them are still truly black boxes, as we say.
Meaning, we don't really know what's in them yet.
And more mechanistic data are coming.
However, when you look over the data in this reviewer, when I look over the data in this
review, what you find is that they're pretty striking positive effects of creatine.
And one of the more interesting effects
is that creatine has actually been shown to increase
mania in people that are already manic.
And that's interesting.
We're not talking about bipolar depression today,
but it seems that creatine elevates levels of activation and kind of mood overall.
And you could see why that would be a problem for somebody that's already in a manic phase,
but it actually might be beneficial for somebody who is very low affect and has major depression.
So should you supplement with creatine?
Well, as always, talk to your healthcare provider.
But if you're somebody who is thinking about things that you can do and things that you
can take in order to improve your mood, keep depression at bay, maybe even support other
treatments for major depression, the creatine system seems like a logical one.
There's at least strong studies and a good number of them to look to to determine whether
or not that's right for you.
I personally take five grams of creatine for other reasons. I take it for the physical performance enhancing effects,
but it's kind of nice to think that perhaps it's also helping me improve my mood.
That's a choice that I've made for me is and within the margins of safety for me in my life.
I don't know that it's right for everybody, but I find it very interesting.
And again, I find it particularly interesting because there's a logical biochemical pathway
to support the finding that it improves mood and can offset the effects of major depression in some cases
or can improve the effects of antidepressant medication in many cases.
When I see mechanism and I see effectiveness and the mechanism and the effectiveness map
to a lot of the same mechanisms that are involved in prescription drugs, that gives me great reassurance
that this isn't just some sort of mysterious pathway or mysterious compound by which creatine
might be working.
So now we've clustered together EPA's exercise and their relationship to inflammation, creatine might be working. So now we've clustered together EPA's exercise
and their relationship to inflammation, creatine
and its relationship to four brain function
and the phosphocreatine system and this NMDA receptor.
And as you'll see in a few minutes,
that NMDA receptor turns out to be vitally important
and is actually one of the main nodes of action
for some of the more novel and exciting therapeutics
that are being explored now in psychiatric clinics.
So let's talk a little bit more about this NMDA receptor
and how it relates to some of the more experimental
or novel therapeutic compounds
for the treatment of major depression.
And the compounds that we're going to be talking about,
you may have heard of before, one is
ketamine, which is getting increasing interest in psychiatric clinics and in various experimental
and clinical studies.
And the other is PCP.
Both ketamine and PCP are known drugs of abuse.
For many years, people have abused these drugs, go by the street name, special K, etc.
And they create dissociative and aesthetic states.
So dissociative states where people don't feel as closely meshed with their emotions and
their perceptions.
It's an odd state, I hear, and it's an odd state that clinicians are now leveraging for
the treatment of depression.
We'll talk about why that is.
But let's talk a little bit about this NMDA receptor and why ketamine and PCP might work for
the treatment of depression or how they even could work.
I want to be very direct that this is an area that still needs a lot of data.
There are, however, some excellent papers from
really terrific groups. One of them is a paper that was published in Nature last year,
2020. First author is Visuna, Sam Visuna, V-E-S-U-N-A, the last author and the lead on the study.
He was Dr. Carl Diceroth, who was a guest on the human lab podcast a few months ago.
It's a world expert in neuroscience.
He's a psychiatrist and this paper from San Vassuna
and Carl and colleagues explored how these dissociative
states come about.
And they looked at this both in animals and in humans
and found that there was essentially a common mechanism
whereby a particular layer
of cortex, so your brain has this outer shell of tissue that is called the neocortex.
It's where our perceptions lie, it's where our associations lie, it's a very important
area for processing, decision-making, and planning, etc.
It's literally stacks of cells and one of those layers in the stack of cells is layer
five.
And the layer five neurons in particular went into a particular rhythm of electrical activity.
This one to three hertz rhythm after mice or humans were administered ketamine or PCP.
There was activation of a particular area of the brain,
this retro splenial cortex as it's called.
And the dissociative state that emerged was an interesting one
and clinically what's described in the trials for ketamine
and things like it, that people who are depressed will take ketamine, will experience a kind of
separateness from their grief and from their emotions, and that possibly there's plasticity,
there actually shifts in the neural circuitry such that their emotions don't weigh on them so heavily.
I'm using very loose language here, but that they don't feel as overridden or as burdened by
their own emotions as they did previously to the ketamine therapy.
Now, absolutely in no way, shape or form, am I suggesting that people run out and take
ketamine in order to treat their own depression?
These drugs are still very much experimental, although they are approved in certain contexts,
at least in the US, by prescription
for the treatment of depression.
What's interesting to me is that these dissociative states sound, at least at the outset, to be
more of a separateness from everything.
It sounds a little bit like depression itself.
It's sort of like a anhydonia and inability to experience pleasure.
And then one takes the dissociative anesthetic and somehow is able to get relief by getting
even further away from an experience.
To me, that doesn't make sense, but that just speaks to the fact that these drugs and
these receptors and these pathways operate through very cryptic means.
And we really don't understand all the pathways in the brain that relate to motivation and mood and so forth.
And the results with these ketamine trials are looking very promising.
In fact, there are a number of trials that show that a fair number of people that take ketamine in a therapeutic setting,
legally with psychiatrists guiding the experience, are able to get relief from their symptoms without the need for
many, many treatments with the drug.
Just how many treatments varies from individual to individual, but it's not like people have
to take this stuff on going.
This is really an attempt to tap into this NMDA receptor that is related to neuroplasticity.
Both ketamine and PCP essentially act as antagonists, which means they block the NMDA receptor.
They do it through different methods, non-competitive and competitive for you, chemist and pharmacologist
out there.
You can look it up if you like.
But what's, therefore therefore even more surprising is that
every neuroscientist learns that activation of the NMDA receptor, not antagonism or blocking
of the NMDA receptor, leads to changes in neural circuitry in very profound ways. In fact,
experimentally, and I've done these experiments myself, if you want to prevent plasticity, you want
to prevent an experience from reshaping neural circuitry.
You give an NMDA receptor blocker.
I've done that many times in the course of my experimental neuroscience career, not to
myself obviously, but in the course of doing experiments.
So it's still a bit mysterious to me how this could work.
A couple of things.
One is this layer five activation is pretty interesting. We're
going to come back to layer 5 when we talk about yet another emerging treatment for depression,
which is psilocybin, so-called magic mushrooms. And the effects of psilocybin on layer 5 neurons
in the cortex. So there's a common theme emerging here, which is that layer 5 activity in the cortex. So there's a common theme emerging here which is that layer 5 activity in the cortex
may be important for rewiring the brain in certain ways that can lead to recovery or to an
alleviation of some of the symptoms of major depression. So if this is sounding a little bit
vague to you, it's because this is still truly experimental and new and still very much on the cutting edge
of what's happening now, we don't have all the answers.
So if it sounds like I'm moving slowly through this
and I'm being extra careful about what I say,
you are correct, you're on 10, I are correct in this case.
I never wanna misstep and say something that's not true,
but that's especially the case
when we're talking about experimental therapies and drugs, which formally we're taken as drugs of abuse, which
are now being used as drugs for therapeutic treatment and the clinic.
There is a very interesting study.
This was published in Science in 2019.
These are very recent studies.
The last author on this is Liston LISTON. The title of the paper is Sustained Rescue of Prefrontal Circuit Dysfunction by Anti-Depressant
Induced Spine Formation.
And here when we hear spine, we're not referring to spine as in your vertebrae running down
your spinal column.
We're talking about the spines, which are these little protrusions on neurons.
Neurons are not smooth by any stretch.
If you zoom in on a neuron, if you were to come to my lab and look down the microscope
and a neuron and zoom in on it, you'd find that some neurons are smooth, but most neurons
have these little protrusions, and those little protrusions are called spines.
Those little spiny protrusions are little sites where neurons can reach out and form and
receive new synapses
from neighboring neurons.
So they increase the surface area of a neuron and allow new connections to be formed.
And so spine formation is synonymous with neuroplasticity, which is synonymous with changes in
circuit function, which is synonymous with changes in the ways that we think, we feel,
and we behave.
And what was shown in this study is really interesting.
What they showed is that ketamine
can relieve depressive symptoms rapidly
by changing or increasing, in this case,
the spines on these neurons in the prefrontal cortex.
And if that word prefrontal rings about,
well, now you remember, the phosphocreatine system,
the ingestion of creatine monohydrate, and the forebrain activation of the forebrain
were related to, in some way or another, to relief or improvement of major depressive
symptoms.
So we're trying to converge on a picture here whereby these drugs, ketamine, PCP,
used in a therapeutic context,
maybe increasing neuroplasticity,
literally the changing of neural circuits in the forebrain,
somehow through dissociative states.
And I don't want to speculate too much
about how that might come about.
But one of the things that's such a resounding or repeating theme of major depression is that
when you talk to somebody who has major depression, it is a real downer. And I'm not being
disparaging of those people. But if you've ever had a conversation with someone who's depressed,
they're always talking about how exhausted they are. Or in really severe cases, they are
not even responsive at all. They just kind of stare at you blankly or they fall asleep.
I mean, they're truly depressed.
Their system is lowered in terms of its activation state.
So I think that it's interesting that the application of drugs
that allow people to separate from that state of not caring or being uninterested or unwilling to do
anything is actually one of
the paths to treatment.
It's not always about just getting people peppy and excited and happy.
There also seems to be a requirement for getting them distanced from their own grief.
And this brings us back to something that we talked about way back at the beginning of
this episode, which was this particular feature of the anti-self-confabulation, that
everything that happens is a reflection that I should say for the depressed person, that
everything that happens is a reflection of how life is bad and their experience is just
point to the fact that nothing is going to get better.
This is the common language of depression.
If there's very depressing to hear me talk about, it is heavy.
And that's what it's like to hear these things.
It's even heavier, of course, for somebody to experience them.
And those beliefs, those patterns of guilt and grief
and anhedonia and delusional anti-self-confabilations,
those are the things that eventually,
if they get severe enough,
start to convert into things like self-harm mutilation
and in the most tragic of cases, of course, suicide.
And so I think we can look to these treatments, such as ketamine and PCP, but in particular
ketamine and its use in the clinic, as ways for people to get distanced from the negative
affect that they feel isn't just inside them or overwhelms them
but that for the very severely depressed person they feel is them and we hear this sometimes you are not your emotions
You know that's a statement that I've always been a little bit challenged by I mean yet. Yes indeed emotions are not
Who we are they are states that we go into and out of, including happiness and sadness,
but they are very much a part of us when we experience them.
We don't experience them as next to us or behind us
or across the room from us.
We experience them as our emotions.
They are so much part and parcel with our experience
of ourself that a statement like we aren't our emotions
is a very hard statement to digest,
especially for the depressed person.
And so I think that the NMDA receptor and its capacity to induce neuroplasticity circuit
changes, the fact that PCP and ketamine are both showing activation of neural circuits
by way of suppressing activity of the NMDA receptor and some of the positive or exciting therapeutic
outcomes that are coming from this really point to the fact
that ketamine and PCP and removal of negative experiences
or the experience of a negative experience,
sort of getting metah there,
but the experience of a negative experience
may be an important path by which people treat their depression,
especially in its most severe forms
where people are revering towards self-harm mutilation and suicide. So you may have noticed a theme
which is that certain categories of approaches that we've been discussing for
offsetting the symptoms of depression such as exercise, ingesting EPAs,
reducing inflammation, or even the SSRIs for increasing serotonin. Focus on
changing some core biological function,
like raising the amount of a chemical serotonin
or reducing the amount of inflammatory cytokines
in the brain and body.
And yet, things like ketamine focus more
on rewiring circuitry, changing neural circuitry
so that it functions better in the immediate
and hopefully in the long term as well and keep people with
major depression in what they call remission away from major depression.
Another category of treatments that's being actively explored now in laboratories and in the psychiatry realm are the psychedelics.
And that's a huge category of compounds. However, one in particular, psilocybin is one that's being most intensely and actively
pursued for its capacity to treat major depressive disorder.
I want to be very clear that the work that I'm going to describe is work that's being done
in university settings, university hospitals, by scientists and psychiatrists, and these are clinical studies,
clinical trials leading to peer-reviewed data.
And those are the data that we'll be discussing.
Some of the major luminaries in this area include, of course, our limited to, but include
people like Matthew Johnson, who's at Johns Hopkins.
We'll discuss some of his work now, and fortunate to say that he will be coming on the podcast as a guest to describe the studies in a variety of laboratories working on
a variety of different psychedelic compounds.
But let's focus on psilocybin for its capacity to rewire neural circuits and alleviate depression.
There have been anecdotal data or evidence over the years that
psilocybin has this capacity, how does psilocybin work?
Well, psilocybin magic mushrooms, as it's sometimes called,
mainly works on what's called the serotonin 5H2A receptor
with some affinity for the 5HT1 receptor.
What does that mean? Well, basically you've got a lot of different kinds of serotonin receptors
just as you have a lot of different kinds of dopamine receptors or other types of receptors.
The advantage of having different receptors expressed in different parts of the brain
and body, even on different parts of individual cells in the brain and body, is that the
same compound serotonin can have a diverse set of effects on different cells and tissues.
This is also the basis of some of the side
effect profiles of SSRIs, because maybe, for instance, we know that taking prozac
loxetine will increase serotonin in one area, but also in another area, and then they will
go have diverse effects on different brain circuits because of the variety of receptors.
Receptors are just like parking slots where the molecule serotonin parks and has different effects.
Well, psilocybin engages or increases serotonin transmission, meaning it increases the amount
of serotonin, mainly by acting at these 5H2A receptors.
But where in the brain does it happen and what are the major effects?
First let's talk about the major effects, because I think that's what people are interested in. The study that I'd like
to highlight is a fairly recent one. It was published in May of 2021 in journal, journal,
excuse me, of the American Medical Association Psychiatry. So, JAMA Psychiatry and it's
entitled Effects of Silicibin Assisted Therapy on Major Depressive Disorder, a randomized
clinical trial. It's an absolutely Disorder, a randomized clinical trial.
It's an absolutely beautiful study, a very important study.
It includes some of the luminaries in this area, like Matthew Johnson, Patrick Finin, Roland Griffiths,
and others. We will provide a link to this study.
It is available in its full form at zero cost, if you want to read it. It's got a lot of details,
so I'm just going to summarize a few things,
but basically what they did was they screened for patients
to come into the clinic.
These were people that suffered
from major depressive disorder
and administered either one or two rounds of psilocybin.
They used particular dosages,
they're listed in the study,
so you can look it up if you're really interested
in that level of detail.
Typically, it was 20 milligrams per kilogram of body weight, so it depends on body weight,
or 30 milligrams of psilocybin per 70 kilograms of body weight.
They were given in capsule forms, so people weren't eating the mushrooms.
This is obviously a very controlled study, and they want to control the dosages appropriately.
They were randomized to begin the treatment immediately or after an eight week delay.
They had all the appropriate control groups that one would like to see.
What's really striking about this study is that there was a very significant improvement
in mood and affect and relief from depressive symptoms in anywhere from 50 to
70% of the people that were subjects in the study who received the psilocybin treatment.
And whether or not it was 50 or whether or not it was 71% varied according to how long
after the study, they maintain these antidepressive effects,
whether or not they stayed in remission from the depression. But these are really enormous and
significant effects. I'm very exciting, and are pointing in the direction of psilocybin very soon
becoming a treatment for various forms of depression, including major depression. Now, of course, this is limited to the laboratory at present.
There are a number of elements of these studies
that are important to take into consideration too,
which is that there are highly trained guides,
meaning people to direct people through the experience.
As Matthew Johnson has told me,
there is the occurrence from time to time
of people having so-called bad trips, of having anxiety attacks during the hallucinations and all that, and they have
ways to mitigate that and deal with that because the guides are trained.
They have all the sorts of medical monitoring devices for heart rate and temperature and
things that one would like to see for a study like this because these are very powerful
compounds.
I don't want to give away any elements of the discussion with Matthew Johnson because it will be released
in podcast form reasonably soon here, the Hubertman Lab podcast. But one of the things that came
up and is a fundamental question that I had that I think probably many of you are asking
is does the experience that one has on these compounds make a difference for whether or not somebody gains
relief from depression from these psilocybin journeys or not? In other words, does it matter what they
talk about? Does it matter what they think about? Does it matter if they have a good trip or a bad trip?
And I don't want to hold you in too much suspense. I'll let Matthew provide the more thorough answer.
But what's really interesting is there are some common themes to
psilocybin administration and experience that lead to relief from depressive symptoms,
but they are subjectively, excuse me, subjectively very varied, meaning that whether or not
people feel they had a good experience or a bad experience, whether or not people thought
about their parents or thought about the color of the ceiling, doesn't seem to have too much
of an impact on whether or not they receive relief during these studies in these clinical
studies.
Seems like different people can have lots of different experiences and still receive
benefit.
And that points to something deeper.
It points to the fact that these drugs,
which is really what they are,
are rewiring neural circuitry in a common way
despite a diversity of experience while on the drug.
And that itself is really interesting,
and it takes us back to a place that we've been before
in this discussion, which is layer five of the cortex,
this area that ketamine seems to impact as well by generating rhythms of the, I mentioned one to three hertz
activity in layer five of certain areas of the cortex.
Well, the 5HT1A receptor is known to be enriched in layer five of the cortex.
And layer five of the cortex is a very interesting area because it's an area in which there's a lot of lateral connectivity.
So connections between different brain areas,
laterally, generally is what allows us to merge different senses.
So for instance, when we hear a sound off to our right over here, we turn to our right.
There's a very hardwired response.
And typically we hear something off to our right, we don't look to our left.
That's how hardwired some of these circuits are. What appears to be happening is that the
activation of the serotonin system in 5HT1A receptor in layer 5 is offering up or providing
an experience whereby the lateral connections are able to engage much more broadly than they would
normally. Now that also could be a bad thing.
And I asked Matt about this, that sounds kind of spooky.
I don't know that when I hear something off to my right, that I want to look off to my
left, that could be highly maladaptive, especially if it's a car coming at me from my
right.
That doesn't seem to be what's happening.
It's not really rewiring these deeply reflexive circuits. It's somehow rewiring associations between events, emotional events, past events, current events,
and future events in ways that allow people to get some sort of relief or distance from
these narratives, these depressive stories about their past and present, and allow them
to see new opportunity and optimism in the future. That's really a fascinating thing, if you really think about it, because I would have thought
that simply by ramping up laterality of connections, meaning the cross associations that things
could either be rewired randomly in ways that don't serve us or would perhaps just cause
no effect at all.
So is either going to be bad or neutral, but that's not really the way things are turning
out.
Again, these are highly controlled studies.
I do want to emphasize that ketamine, psilocybin, these things are still illegal, most
all places.
There are some regions and cities in the United States where they are locally decriminalized,
but they are not legal.
They are still illegal.
So what we're referring to here are indeed clinical studies
in which people are taking them legally.
I think it's very likely we will see a shift
in the legislature around psychedelics
and in particular, psilocybin in the not too distant future.
And I think that for now, what we should know
is what Matt told me and what you'll hear far more about,
which is that psilocybin, this one,
or in most cases, two dose treatments done
in a highly clinical setting, controlled setting,
with patients that are carefully selected,
can, in many cases, the majority of people receive
and maintain relief from their depressive
symptoms simply through the experience of this psychedelic journey.
I did ask him about microdosing.
I mean, it sounds as if I had never heard about it before.
Microdosing, not microdosing, microdosing.
His answer was interesting.
His answer was that the microdosing effects
don't seem to be nearly as impactful as some of these,
let's just call them what they are,
these kind of high amplitude sessions
that are just one or two.
There are some studies ongoing where there's more than two,
but that the microdosing doesn't seem to compare
to these macrodosing, I that the micro dosing doesn't seem to compare to these macro dosing.
I mentioned the dosages before, this 20 milligrams per 70 kilograms or 30 milligrams per
70 kilograms dosages, I'm given, a couple, given several weeks apart.
So you'll hear more about micro dosing and other psychedelics and their impact on depressive
states and major depression in the episode with Matt.
But for the time being, it really seems as if, again, we're looking at neuroplasticity.
We're coming back to layer five, just like with ketamine and PCP.
We're hearing about layer five.
We're hearing about rewiring of circuitry.
We're hearing about a dissociation or a distancing of oneself from these negative moods
and affects and narratives.
But there's a key distinction between the ketamine work
and the psilocybin work, which is that in the ketamine work,
it really is about dissociating from experience
during the session with the psychiatrist,
whereas during the psilocybin journey,
it's really about immersing oneself in the experience
and being fully present to that experience
that does seem to be an important component.
And what the difference is there and why they both seem to provide some relief from major
depression isn't clear.
I think most likely it takes us back to the fact that this thing we call major depression
clearly involves serotonin, dopamine, endorepinephrine, and in some individuals, they may be more deficient
in one or several of those, or all of those,
whereas in other individuals,
it might be a different collection of chemicals.
And of course, there are a tremendous number
of other psychedelic compounds
that people are exploring for treatment of major depression,
but really psilocybin is the one that we have the most data on.
MDMA has mainly been explored in the clinical realm
for treatment of trauma.
There are some trials ongoing for treatment of depression,
but the big breakthrough seemed to be happening
in the realm of trauma treatment,
the so-called maps group that's doing this,
again, legally in a clinical setting.
And there are other groups that are starting to do it as well.
We are going to do an entire podcast episode about MDMA and some related compounds, so I'll
save that discussion for then.
One of the most common questions I get for this podcast is about different diets, different
regimes, different nutritional plans, things like keto, ketogenic diet, or vegan
diets, or intermittent fasting, or the all-meat diet, the so-called lion diet, et cetera.
There are actually really interesting data relating nutrition and diet to major depressive
disorder.
And I think we just need to frame this by returning to something that was said earlier,
which is that the ingestion of carbohydrates, in particular carbohydrates, and some meats like Turkey that
are rich in trip-to-fan, this precursor to serotonin, are in many ways the self-medicating
version of depression treatment. Now, to be clear, I'm not saying that people should use
food to medicate their depression.
Many people do that reflexively, however,
they reach carbohydrate-rich foods to blunt their cortisol,
because that's indeed what it does.
Blunt's cortisol when you ingest high carbohydrate foods
in particular, starchy foods.
And it does increase serotonin, in particular,
if those foods rather are rich in the amino acid
triptophan. Now ingesting food is wonderful and important and great, but ingesting excessive
foods of any kinds, carbohydrate or otherwise is not healthy, of course. There have been
some explorations of whether or not a vegan diet can improve symptoms of depression, not
a lot of data, not impressive data.
There have been very few controlled studies looking at the carnivore, all meat diet.
On that, I think there are now some that are starting to spin up, meaning the studies
are starting to spin up.
However, the ketogenic diet has been explored for its ability to relieve certain symptoms
of depression.
In particular, to what's called maintained uthymia.
Uthymia is the kind of state of equilibrium
between a manic episode and a depressive episode
in a manic bipolar person.
We'll return to this more in a future episode.
But it basically,
manics have highs and they have lows, bipolars,
either cycle back and forth really quickly.
So rapid cycling bipolars or slow, some people people so really quickly can be day-to-day
Other people it's month to month or week to week. They're going highs and lows and
You hear about mania and you hear about dysphoria. Euphymias that kind of
Place in the middle where people feel neither too high nor too low and
There are some interesting studies looking
at the ketogenic diet for maintaining uthymia
in manic depressives, but also in people
with major depressive disorder.
Why would this work?
Well, we have to remember that the ketogenic diet
wasn't discovered so that self-appointed nutrition gurus
could talk about it online, or so that people could make money selling
anything related to ketosis.
And here I'm not disparaging of the ketogenic diets.
Helped a lot of people.
The ketogenic diet was actually shown to be medically relevant for its use to treat epilepsy.
It turns out that in epilepsy or in particular pediatric epilepsy, that a ketogenic diet
and the shift of brain metabolism to predominantly one in which ketones are being metabolized,
rather than more standard glucose-type metabolism, can greatly reduce the number of epileptic seizures
that these children experience. It's not always the case, but it's often the case. And so you talk to a neurologist who's or a neurosurgeon who's specialized in
in epilepsy and particular pediatric epilepsy and they'll tell you this. Oh, yeah, the ketogenic
diet in many cases, not all can be very effective for this treatment. How? How is it that a ketogenic
diet reduces seizures? Well, the way it reduces seizures is by increasing what's called GABA transmission.
GABA is a substance that is naturally released in our brain.
It's an inhibitory neurotransmitter, meaning that when it's released into the synapse,
it has the tendency to reduce the firing,
reduce the electrical activity of the next neuron or sets of neurons.
There are various compounds that increase GABA. In particular GABA in the forebrain, one common
example would be something like alcohol, drinking alcoholic drink or two, will increase GABA transmission,
will ironically, will lower your social inhibitions by increasing your neurochemical inhibition.
It basically suppresses the self-monitoring pathways.
If people drink enough, it will suppress all pathways and people will urinate themselves
and fall over.
It will eventually inhibit all sorts of pathways.
The GABA system has a rich array of effects all over the brain and body, but alcohol tends to activate the
release of GABA. You might say, well, then why not just take alcohol to suppress seizures?
Well, that would be a terrible idea because there tends to be a rebound excitability after
alcohol stops having its effects on the GABA receptors. And so then there's an excitability
for which an epilepsy would be terrible. The reason why the epileptic diet is useful for epilepsy is that increases the what we
call the tonic level, the sort of the tie, the level of GABA in the brain, and that suppresses
some of the hyper excitability that is the characteristic feature of epilepsy.
And there are other drugs, for instance, the benzodiazepines and things of the Xanax variety,
valium and so forth.
Those increase GABA transmission.
Those drugs also have a lot of potential for abuse and addiction, et cetera, and they're
problematic for other reasons.
But the ketogenic diet, by way of increasing ketone metabolism, or shifting brain's metabolism
over to ketonesones tends to modulate
GABA such that GABA is more active and adjusts the so-called GABA glutamate balance. This
is getting technical, but glutamate is an excitatory neurotransmitter. GABA is inhibitory
neurotransmitter, and their balance is vital for neuroplasticity, for maintaining healthy levels of activity in the brain,
et cetera.
And so there is decent evidence
that people with major depressive disorders,
in particular, the people with major depressive disorders
that are refractory, meaning they don't respond
to classical antidepressants can benefit, it seems, from the ketogenic diet.
Now this is not always the case, but for those of you out there who are struggling with
major depression and for which drugs have not worked, please talk to your psychiatrist.
I don't know how many of them are up on the literature about the ketogenic diet or the
EPA's and the rest.
You know, psychiatrists are very in terms of how involved in
the current literature, they tend to be, but there are many excellent psychiatrists out there. Most
of them, in my experience, are actually quite avid learners about what's happening and what's new
in this realm that they call psychiatry. So it's really interesting that eating in a particular way,
lowering carbohydrates to the
point where you rely on ketogenic metabolism in the brain increases GABA and can provide
some relief for depressive symptoms.
And that in particular, that seems to have positive effects in people that are refractory
or don't respond to classic antidepressants.
And that would include things like fluoxetine, et cetera.
I'll make one final point about ketogenic diets and GABA and depression, which is that it's also been shown that
for people that respond well
to these drugs that impact the serotonin system dopamine system or noripinephrine.
The ketogenic diet there may
improve the
ability for those drugs to work at lower dosages, which is
reminiscent of what we saw with the EPA supplementation.
So today we've covered what at least feels to me like a tremendous amount of material.
This topic of depression is indeed an enormous topic to try and get our arms around.
We talked about the symptomology.
We talked about some of the underlying neurochemistry and biology.
And then we talked about approaches to deal with it that are really grounded in the neurochemistry and biology.
I just want to recap a few of those tools
and what those things are.
First of all, we talked about making the effort
to not overwhelm the pleasure system.
That might seem counterintuitive,
to not overly seek out pleasure
or else one can find themselves in a place
of depression.
I mentioned way back at the beginning of the episode, a young man who I know to be really
struggling with depression and it is thought and we don't know for sure, but it is thought
that some of that depression was probably triggered by an overindulgence in video games
and other highly dopaminergic activities to
the point where those activities eventually were countered by the pain balance that Dr.
Annelamki described.
And he now has to do those activities repeatedly and for many, many hours each day, just to
feel okay, not even to derive pleasure from them.
And worse, many other activities, practically all
other activities have lost their zest, they've lost their excitement and there's and his
sense of pleasure for them.
And so there's a really active campaign now to reset that system.
So number one, don't overwhelm your pleasure centers either through activities or compounds.
I'd seem counterintuitive, but you're setting yourself up for anodonia and depression if
you do that.
It's not just about addiction, that too, but it's also about setting yourself for anodonia
and depression.
How often can you engage in these activities?
Well, that's going to differ from person to person, everyone's slightly different.
But you should really mind your extreme highs and your extreme lows and be cautious about those.
We'll probably have Dr. Lemke on again at a future time to try and get some more specifics
about that, but if you do feel like you need to reset that system, it really does seem
like a 30-day, complete detox from whatever activity your substance that is, and ideally
it doesn't continue after that 30 days, especially in conditions of drugs of abuse.
Second of all, talked about the norapeneference system and how the norapeneference system
is really deficient in many forms of major depression and in depression.
There is now more deliberate pursuit of norapeneference inducing activities that are healthy, that
aren't adrenaline seeking
per se, things like cold showers, things like particular patterns of breathing that engage
and tend to make us more alert. Things like exercise that will increase our levels of
noradrenaline. I'd be remiss if I said that these activities could completely eliminate
depressive symptoms in people with
major depressive disorder.
I don't think that's the case.
And again, I want to acknowledge that people with major depressive symptoms often don't
have the energy, the willingness, or the capacity to engage in some of these activities.
But things like cold shower, deliberate cold showers, things like regular exercise, they
aren't just feel good activities. They actually engage the
Norepinephrine system and keep that system tuned up and allow us to increase our Norepinephrine
levels at will on a regular basis, and their mood enhancing effects are real effects that at the
level of neurochemistry. Then we talked about EPA's essential fatty acids, and it's clear that
for most people getting above a thousand milligrams and probably even closer to
2,000 milligrams per day of EPA's can be beneficial for mood, especially in attempts to treat or offset
major depressive disorder. Are there side effects? Well, you need to explore those for yourself and with your doctor,
everyone has a different health background. You know, for the margins of safety for most people will probably be quite large,
but for some people, that might not be the case.
So definitely, definitely check with your physician.
We also talked about exercise and how EPA and exercise on a regular basis can offset these
inflammatory pathways.
I want to mention something I've mentioned on a previous podcast, but in terms of keeping
the inflammatory all these molecules that create inflammation and then the inflammation
can limit the amount of serotonin
through the pathways we described.
In order to do that, it's also very, very useful
to ingest two to four servings of fermented foods
on a daily basis or near daily basis.
These are data that were published by the Sonnenberg Lab.
It's Stanford recently in the journal Cell,
Cell Press Journal, excellent journal,
that ingestion of these fermented foods really keeps the gut microbiome tuned up, so to
speak, well, in order to offset these inflammatory cytokines.
Keeping inflammation at bag, it just turns out to be a really good thing in order to keep
our mood in a good place.
So EPA exercise fermented foods creatine as a potential source of relief
from depression or offsetting or keeping us away from major depression or relapse into
depression. And then we talked about the prescription compounds and the compounds that are being
used mainly in the course of studies and of psychiatry and depression, things like ketamine,
PCP, psilocybin and related compounds. And then lastly, we talked about ketosis, which
may not be right for everybody, but might be right for certain individuals out there who are grappling with this.
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