Huberman Lab - The Science & Treatment of Bipolar Disorder
Episode Date: July 25, 2022In this episode, I explain the biology, symptoms, causes and types of bipolar disorder (sometimes called bipolar depression). I discuss neuroplasticity and how the brain normally regulates mood, energ...y, and perceptions; then, I contrast that with the biology of bipolar disorder, which is characterized by extremes of energy and mood, e.g., mania and depression. I outline the mechanisms through which bipolar disorder manifests in the brain, including deficits of interoception and reduced connections between the parietal and limbic systems. I also outline how treatment options (such as lithium) work in part through homeostatic plasticity.’ I discuss not only lithium but also the treatment of bipolar with ketamine, different talk therapies, electroconvulsive therapy, transcranial magnetic stimulation, and nutraceuticals, including Omega-3 and Inositol supplementation. This episode should interest anyone who has or knows someone with bipolar disorder and, more broadly, those interested in how the brain works to create a balance between thoughts, energy levels, focus, and mood. 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) Bipolar Disorder (00:03:42) Tool: Appetite Suppression & GLP-1, Parallel Pathways, Yerba Mate (00:9:19) Sponsors: AG1, LMNT (00:14:24) Prevalence & Severity of Bipolar Disorder (00:16:30) Bipolar Disorder I, Diagnostic Criteria of Mania (00:28:58) Bipolar Disorder II, Individual Variability (00:33:07) Bipolar I vs. Bipolar II: Manic, Depressive & Symptom-Free States (00:38:20) Consequences of Bipolar Disorder, Heritability (00:46:53) Bipolar Disorder vs. Borderline Personality Disorder (00:51:51) Mania & Depression, Negative Impacts (00:53:06) History of Lithium Treatment (01:02:44) Lithium Treatment & Side-Effects (01:05:05) Effects of Lithium: BDNF, Anti-inflammatory & Neuroprotection (01:10:10) Neural Circuits of Bipolar Disorder, Interoception, Hyper- vs. Hypoactivity (01:17:11) Neural States & Mania, Parietal Lobe & Limbic System (01:22:58) Homeostatic Plasticity, Synaptic Scaling, Lithium & Ketamine (01:36:00) Talk Therapies: Cognitive Behavioral Therapy, Family-Focused Therapy, Interpersonal & Social Rhythm Therapy (01:43:18) Electroconvulsive Therapy (ECT), Transcranial Magnetic Stimulation (rTMS) (01:48:01) Psylocibin, Cannabis (01:51:50) Lifestyle Support, Supplements: Inositol & Omega-3 Fatty Acids (02:03:31) Omega-3s, Membrane Fluidity & Neuroplasticity (02:06:44) Mania, Creativity & Occupations (02:15:33) Bipolar Disorder: Diagnosis, Neural Circuits & Treatment (02:17:45) Zero-Cost Support, YouTube Feedback, Spotify & Apple Reviews, Sponsors, Momentous Supplements, Instagram, Twitter, Neural Network Newsletter Title Card Photo Credit: Mike Blabac Disclaimer
Transcript
Discussion (0)
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. Today, we are going to be discussing bipolar disorder often called bipolar depression.
Bipolar depression is a condition in which people undergo massive shifts in their energy,
their perception, and their mood. However, it is very important to note that the shifts in
mood, energy, and perception are all maladaptive. They can often cause tremendous damage to the
person suffering from bipolar disorder and tremendous damage to the people in their lives.
Today, we're going to parse the biology that leads to the shifts in mood, energy, and perception.
And we are going to talk about the various treatments that exist.
Some of those treatments have been around for a very long time, and indeed one of those
treatments, Lithium, has an incredible backstory about its discovery, and in understanding how
Lithium works, and some of the ways in which it does not work well,
it reveals a tremendous amount about how the brain works normally in all individuals.
So that's a miraculous story that I look forward to sharing with you.
As we go forward in this discussion about bipolar disorder,
I want everyone to keep in mind that it is a very severe condition.
In fact, people suffering from bipolar disorder are at 20 to 30 times greater risk of suicide.
So today is a serious discussion, and it's certainly one in which people who are suffering
from manic bipolar disorder or who know people that are suffering from manic bipolar disorder
can benefit from.
However, for those of you that might know people or who themselves suffer from major depression,
we will also be talking about important treatment developments for major depression.
Major depression is a very common thing for many people. In fact, most people will suffer from depression of some sort at some point in their life,
although not necessarily a major depressive episode, and yet major depression is very common.
So you'll soon learn up to 20% of people will suffer from major depression. So today's discussion will encompass all of that, and it will also encompass
basic brain mechanisms of neuroplasticity, the brain's ability to change in
response to experience both for good and for worse, and you'll learn a lot about
the basic biology of how the brain regulates mood, energy, and perception.
Before we dive into the discussion about Manifolder Disorder,
I want to highlight some recent findings
in an area totally separate from mental health
that I think are really important for everyone to know about.
This is a paper published in the journal Cell,
which is a Cell Press Journal, an excellent journal.
In fact, one of the three Apex journals,
so for those of you that are curious,
papers published in the journal Nature, Science, and Cell,
are considered the sort of
Super Bowl Stanley Cup and NBA Championships of Publishing. And this paper
entitled An Interorgan Neural Circuit for Apatite Suppression illustrates a very important principle that I think everyone should know about. And that's the principle of so-called parallel
pathways. Parallel pathways, as the name suggests, are pathways that could be neural pathways
or hormonal pathways or otherwise, that operate independently of one another to accomplish
a common goal. And what this paper really shows is that there's a set of peptides in the
body and the peptide that I'm referring to today is called GLP1, glucagon-like peptide
1 and some related peptides.
I've talked about these on the podcast before
for two reasons.
First of all, I'm a big proponent and consumer
of Yerba mate, Yerba mate is a tea
that can promote the release of Glucogon-like peptide 1.
And there are also new prescription drugs
that are now hitting the market,
and for which there are really impressive clinical trials for diabetes and obesity that are essentially glucagon
like peptide-1 stimulator, so they stimulate the release of that, or they are in fact a
synthetic version of glucagon-like peptide-1.
What is glucagon-like peptide-1?
It is a peptide, which is a small little protein that can dramatically suppress appetite.
So that's why these drugs are being explored and are showing quite impressive results for
things like treatment of type 2 diabetes and other forms of diabetes as well as obesity.
So they lead to weight loss.
Now in terms of the yearba mate stimulation of glucogon like peptide one, that's going
to be a much lower amount of glucogon-like peptide one that's released from drinking
yerbamate, as opposed to, say, taking a drug that stimulates GLP1 or taking a drug that is GLP1.
Nonetheless, I should also point out that yerbamate comes in a bunch of different forms.
There is some concern about certain smoky flavored forms of yerbamate being carcinogenic. So that's why I avoid those forms of yerbamate being carcinogenic.
So that's why I avoid those forms of yerbamate.
But for me, yerbamate is one of the preferred sources of caffeine.
For me, I like the way it tastes.
It does provide that sort of caffeine kick that I like to have early in the day for focus and for work and for exercise.
And yet, I actively avoid the smoked varieties of yerbamate
because of the potential carcinogenic effects of the smoked varieties of yerba mate because of the potential carcinogenic effects of the smoked varieties.
Glucogon-like peptide one, as I mentioned earlier,
can suppress appetite, but what this paper shows
is it does that by at least two mechanisms
through parallel pathways.
What this paper shows is that
Glucogon-like peptide, one, axon receptors in the body
in a portion of the nervous system
called the enteric nervous system,
ENT, ERIC, enteric nervous system.
This is a component of your nervous system
that you don't really have control over.
It's autonomic or automatic.
GLP1 binds to what are called intestinofugal enteric neurons.
You don't need to know the name,
but those neurons do two things.
First of all, they cause some gut distinctionension. So they actually make you feel full. This is incredible, right?
A peptide, not actual physical food, but a peptide that stimulates neurons that cause changes
in the so-called mechanoreceptors of the gut of the interrac nervous system and make people
feel full. So it can lead to actually mild
or I suppose if levels of GLP1 are very high
to major gut distension, okay?
I think that the levels of GLP1
that would come from drinking your bomote
and hopefully from appropriate dosaging
of the synthetic forms of GLP1 or drugs
that stimulate GLP1 would cause mild
not major gut distension
because major gut distension would be uncomfortable.
So GLP1 is acting at the level of gut to increase gut distension and by way of a pathway that
goes from the gut up to the hypothalamus, this little cluster of neurons about the size
of a marble that sits above the roof of your mouth, is also suppressing appetite through
brain mechanisms.
So this is really beautiful, right?
You have a peptide, a small little protein that's released in the gut, and that release within the gut causes gut distension, which
makes you feel full. And by way of neural stimulation of the hypothalamus also activates
neural pathways within the brain that trigger satiety, the feeling of having had enough food.
So to me, GLP1 is both impressive and important. Why?
Because this recent category of drugs that's now hitting the market seems to adjust obesity
or can help people with weight loss in order to help their health.
And it's doing so by at least two mechanisms.
One is within the brain and the other is within the gut and communication through the so-called
gut brain access.
Because again, these interterrains are communicating to the brain, the hypothalamcalled gut brain access because again, these interterrons are communicating
to the brain, the hypothalamus, by way of this,
what's called the sympathy gastro-spinal reticular
hypothalamic pathway you absolutely do not need to know.
All of that, that's a mouthful,
that's enough to make your mouth feel distended.
But at the same time, things like yerbamate,
and I'm sure there are other compounds out there as well,
but certainly yerbamate can stimulate the release of GLP1.
So for those of you that are looking for some mild appetite suppression and want to accomplish
that while also ingesting caffeine, yerba mate might be a good option for that and just
know that it's operating through two mechanisms on the body through mild gut distension to make
you feel full and on the brain to increase satiety or make you feel less hungry.
And then for everybody, not just those that are interested in appetite suppression, I think
it's important to understand that these parallel pathways are fundamental to how we are organized.
Another good example of this would be when we are excited by something positive or negative,
so it could be stressful or we're positively aroused.
There is a parallel activation of epinephrine adrenaline, both from your adrenals and from
an area in the brain called the locus serulius.
So again and again, we see this in biology and in neuroscience, that your brain and your
body are acting in concert.
They're acting together through mechanisms that either are independent, so separately in
the brain and separately in the body, but directed towards a common goal or through communication
between brain and body and almost always that communication
is going to be bidirectional body to brain and brain to body.
So I think these results are really interesting and really important for sake of weight loss,
for sake of appetite suppression and just generally for the way that they illustrate this
very important theme of the way that we are constructed at a biological level, which
is parallel pathways.
Before we begin, I'd like to emphasize that this podcast is separate from my teaching
and research roles at Stanford.
It is, however, part of my desire and effort to bring zero cost to consumer information
about science and science-related tools to the general public.
In keeping with that theme, I'd like to thank the sponsors of today's podcast.
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I've been taking Athletic Greens since 2012,
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The reason I started taking Athletic Greens
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interacts with your immune system, with your brain to regulate mood, and essentially
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Let's talk about bipolar disorder.
And today I'm going to refer to bipolar disorder interchangeably with bipolar depression,
although as you will soon learn, not everyone with bipolar disorder necessarily goes through
highs and lows.
There is a subset of people who suffer from bipolar disorder who experience the manic phases,
the highly elevated mood and energy, and then drop down to so-called baseline.
So they don't necessarily go down into a depressive state.
They often will return to a somewhat normal state.
In fact, we will talk about the percentage of time
that people with bipolar disorder
tend to be symptom-free, manic, or depressed
in the context of the different categories
of bipolar disorder.
But as we wade into this topic that is bipolar disorder,
I just wanna give you a little bit
of the background statistics to anchor us
in just how serious and prevalent bipolar disorder is.
So bipolar disorder impacts about 1% of people.
That might seem like a small percentage.
But if you think about a room of 100 people, that means that at least one of them is very
likely to have bipolar disorder.
And as I mentioned earlier in the introduction, bipolar disorder is very serious.
It has a 20 to 30% greater incidence of suicide than the general population, which is, first
of all, extremely tragic and extremely concerning.
So anyone that thinks they might have bipolar disorder, or who knows someone with bipolar
disorder should be especially vigilant about this.
And we'll talk about some of the signs and risk factors, age of onset, et cetera, as
we move forward.
So 1% of people have bipolar disorder.
The typical age of onset is anywhere from 20 to 25 years old, although it can be much
earlier.
And the earlier the onset of a bipolar episode, which we will define in a few minutes, the
earlier the onset of that episode, the higher likelihood that the bipolar
disorder is going to be a stable feature of that person's psychology going forward. And yet,
I also want to point out that there are some very good treatments for bipolar disorder
that those people could still benefit from. There are basically two kinds of bipolar disorder
referred to as bipolar one and bipolar two. So let's just talk about bipolar one first.
Bipolar one is characterized by a fairly extended period of mania.
What is mania?
Mania is a period of very elevated mood, energy, distractability, impulsivity, and some other
symptomology that we'll talk about going forward.
But this manic episode is extreme.
This is a condition in which the energy left, the mood left,
and the sort of impulsivity and actions and words of the person
suffering from manic bipolar disorder are very noticeable and very extreme.
Now, a key thing, however, is that it's not always noticeable to the person suffering from it, that they are in this mode.
Sometimes they recognize that, sometimes they don't,
but it's always highly recognizable to other people
that the person suffering from manic bipolar disorder
is not like other people.
So let's talk about bipolar one in a little bit more depth.
One of the key clinical criteria,
or diagnostic criteria for Bipolar 1 is that a person
suffer from these manic episodes or display these manic episodes for seven days or more.
That turns out to be very key.
The stability of that manic episode for seven days or more turns out to be very important.
And for those seven days, the person is in an elevated mood, expansive
thought all day, every day for those seven days. Now, there are a lot of reasons why somebody
could be in a manic mode. It doesn't necessarily mean that somebody has bipolar disorder. In fact,
someone could be in a manic mode for seven days or more and still not be diagnosed with bipolar
disorder. Why? Well, there are other things
that can create manic episodes, things like traumatic brain injury, things like seizure, things like
various prescription drugs or illicit drugs, things like amphetamine and cocaine. That is not the same
as bipolar disorder, even though from a symptomology perspective, they might look even identical. So,
let's think about these symptoms
and the diagnostic criteria that a psychiatrist would use
in order to ask whether or not someone is manic
because they have manic bipolar disorder
or whether or not that person is manic for some other reason,
such as traumatic brain injury, illicit drugs, et cetera.
So typically a person would be brought into a clinic or a person would bring themselves
to a clinic or meet with a psychiatrist.
It seems more likely that they would be directed toward a psychiatrist because oftentimes people
who are in a manic episode just simply won't have the perspective or the foresight to bring
themselves into the clinic.
And the psychiatrist is going to start to evaluate for a couple of different
things.
But first of all, what they're going to try and figure out is whether or not the person
has at least three of the following symptoms.
The first symptom is distractability.
Is the person distractable?
Are they going from one thing to the next?
People who are in a manic episode will be talking about a pen and then they'll be talking
about something they saw the other day and then something they want to purchase and then
a place they're going to travel to, etc.
But they are also very prone to any stimulus within the room, meaning a bell could go off
or there could be a sound out in the hallway and they'll orient to that and then they'll
orient to the clinician and then they'll orient to something in their pocket.
So they're all over the place.
You could think of this a little bit like ADHD or attention deficit disorder, but it's
very extreme.
So highly distractable, highly impulsive,
impulsivity relates to actions.
So the person might be fidgeting with something
and then they might try and leave the room
or the person might, if they were out in the real world,
somebody might notice that the person is going
and purchasing multiples of something
that would be unusual for someone to purchase.
So for instance, I happen to know someone whose expaus had bipolar disorder and their expaus
went out and bought 10 plus air friars.
I mean, I think unless you're a restaurant that's using a lot of air friars, the idea that
you would need more than one or two air friars might just seem a little bit out of the norm.
And so that impulsivity can be purchasing,
it can be other things as well.
It can be booking 12 international trips in one afternoon
or going and buying three cars, et cetera.
So impulsivity.
The other is grandiosity.
People who have manic bipolar disorder,
who are in a manic episode, will often display words of
or actions of grandiosity.
And keep in mind, these are not lies in the sense a manic episode will often display words of or actions of grandiosity.
And keep in mind, these are not lies in the sense that the person isn't lying in order
to try and pull one over on anybody.
These are actual beliefs that the person comes to have about their grandiose position in
the world or grandiose opportunities or potential in the world.
Typical forms of grandiosity and manic episodes would be that the person suddenly decides
that they are going to win a Pulitzer Prize, that they are the person selected to win a Pulitzer
Prize, they're going to write a novel that afternoon and they're going to win a Pulitzer Prize
that year, which is more or less a delusion of grandeur, right? The idea that someone could do
that in one afternoon, I suppose it is possible in the realm of all possibilities, but it's extremely unlikely.
Other forms of grandiosity that often present themselves in people suffering from a manic
episode will be that they're going to run for president or that they are the person that
they believe is selected by the citizens of a given country or by the universe to be the
president of that country or to be president
of the universe, right?
It sounds ridiculous, but those sorts of delusions of grandiosity are one condition that often
presents itself or one set of symptoms that presents itself.
Flight of ideas are also typical of manic episodes.
So this is a little bit like distractability, but this would be people talking extensively
about one thing and then switching and talking extensively about something else.
It would be as if I was doing this podcast talking about manic bipolar disorder and then suddenly
switching to OCD and then to deliberate cold exposure and then to the role of sugar and
its impact on the brain, etc.
So essentially a random selection of the different topics that exist in science, all of which
I happen to be very interested in and curious about,
but just as we have episodes of the podcast that are about one or two topics and we focus on those in a fairly narrow
trench of discussion, somebody who has a flight of ideas would be jumping between categories and topics
in a kind of pseudo-random way, so they might take off down a path of one thing and then switch to another
without any transition or with transitions that don't have any logical structure to them.
The other aspect of manic bipolar disorder that often presents itself in the manic episodes are
agitation. People feeling extremely physically agitated, so a lot of shaking and moving about.
This can venture into the realm of paranoia, but a lot of agitation, a difficulty sitting
down and being still, a difficulty, and just looking, feeling, and acting calm.
And then another condition is no sleep.
And when I say no sleep, I mean no sleep, or very minimal sleep.
As incredible as it sounds, people who are in a manic episode can often go seven days or more with zero sleep.
And a key feature of this zero sleep is that they're not troubled by it. They're not thinking,
oh, I'm suffering from insomnia and I really, really want to sleep. Sometimes that's the case.
But more often than not, they are simply not sleeping. They're staying up 24 hours. Then another 24 hours
it just continues for an entire week. Again, inconceivable
to those of us that don't suffer from manic episodes, can only imagine how pulled apart
most of us would feel under those conditions. And yet, they are just going and going and
going and going with no sleep up all hours, shopping, talking, running, doing all sorts
of different things in the categories of other symptoms
that we talked about before, and it doesn't bother them that they're not sleeping.
And then the last sort of category of symptoms that the psychiatrist is evaluating for and
seeing if they present is rapid pressured speech.
The rapid pressured speech is something that when you hear it, you recognize it.
This is somebody that almost seems to be hitting you with speech like machine gun fire.
It's coming at you, coming at you, coming at you, and there's really no room for conversation.
They're not offering any opportunity for a back and forth, or if there is a back and forth,
they might ask you how you feel about something and then you start, well, then they're coming
to them, then they're going to hit you with another barrage or a paragraph of information
or of just speech that that pseudo-random.
So we've got distractability, impulsivity, grandiosity, flight of ideas, agitation, no sleep,
and rapid pressured speech.
For someone to be diagnosed as in a manic episode, they do not have to be engaging in or displaying
all of those symptoms.
They do, however, need to present at least three of those symptoms.
And then in order to meet the condition of bipolar one, they have to be presenting those three
symptoms for at least seven days.
It could be longer, but at least seven days.
Now this seems pretty straightforward, right?
One level, the way that I described this and the way that it exists in the clinical literature,
you could think, well, this should be pretty easy to diagnose.
And yet, there's a complication there or a challenge there
because the psychiatrist, again, has to determine
that these manic episodes are not due to something other
than bipolar disorder.
For instance, again, it could be TBI,
traumatic brain injury, it could be seizures or or meds, or other sorts of drugs.
Cortical steroids, which are often prescribed for a number of immune conditions or for wound healing,
can also cause manic episodes. So they have to determine that everything that's happening
meets the criteria I described before, three out of seven of these symptom categories for seven
days or more, and that it can't be better explained by something else going on in
that person's life or immediate medical history. That's very important. Now the other challenge and
this is something that's going to come up again and again today, not just in the description of the
biology of bipolar disorder, but also in the description of different treatments and treatment
approaches, is that typically when somebody is sitting in front of a psychiatrist,
in particular for the first time, those two people are interacting, the psychiatrist is
just getting one snapshot of the person at that moment, right?
So the person could be on day one of a manic episode, the person might be on day six of
a manic episode.
The person could be transitioning out of a manic episode. The person could be transitioning out of a manic episode
or the person could be suffering from a combination
of manic episode where because of the impulsivity
of bipolar disorder, they went out and used illicit drugs,
they also used cocaine.
So the psychiatrist has this serious challenge.
The psychiatrist has to determine
based on a conversation, right?
This isn't a blood test.
This isn't a measure that you can take on a scale
or with a biomarker.
They have to use language, a conversation with somebody
who by all accounts is pretty impaired at conversation
to determine whether or not they're suffering
from a manic episode that is the consequence
of bipolar disorder.
You can imagine this in the real world as somebody says,
well, how long has it been since you slept? And the person starts to answer, oh, well, the other day I went down to the basement,
I was going to get something out of the refrigerator and I thought I might take a nap and then all of a
sudden they're talking about something completely different. So they might not even have an answer.
So the psychiatrist has to be a really good detective, a benevolent detective, but a detective nonetheless.
In determining whether or not these symptoms have existed for seven days or more, and whether
or not they meet at least three, it could be more, but at least three of the criteria
of symptom categories I talked about before.
Now assuming that they do, assuming that the patient meets those criteria, they are likely
to be diagnosed with bipolar one.
Now, bipolar one disorder means they're having these extended manic episodes, seven days
or more, but it does not necessarily mean that they are dropping into a depressive episode
as well.
This is a common misconception about bipolar disorder because, as it's often called, bipolar
disorder is referred to as bipolar depression.
And yet, many people with bipolar disorder don't necessarily experience the deep,
depressive episodes.
Many of them do, but many of them do not.
So somebody can truly be diagnosed accurately
with bipolar one, even though they're only experiencing
manic episodes and then dropping down to baseline.
manic episode, then dropping down to baseline.
That's very important to understand.
Now, the second category of bipolar disorder is bipolar two.
So Bp2 or bipolar disorder two is somewhat different
than bipolar disorder one.
First of all, it's characterized most often
by the presence of both manic episodes,
mania and depressive episodes,
or what's referred to as hypomania.
Now, anytime in biology or in medicine you hear hypoe, it's the opposite of hyper.
Okay?
So we've got normal hyper and hypoe.
Hypomania is a somewhat suppressed level of mania.
So this is not going to be as extreme as the mania that we typically think of.
And yet the hypoe can be due to the duration, not the intensity of mania.
That's right, hypomania can mean a lessened intensity
of mania, but it can also be used to refer
to a shorter duration of mania.
In fact, that's one of the key criteria for bipolar two.
Bipolar two is often diagnosed on the basis
of the presence of manic episodes
that are lasting four days or even less.
So someone with BP2 might have four days
of this increased energy,
goal-directed activity, they're irritable,
they're euphoric, they're not sleeping, et cetera,
but it's only lasting for about four days.
Or they could be having longer extended periods of mania,
but they are hypomanic episodes.
They're not quite as intense.
So the pressured speech isn't quite as pressured.
The impulsivity isn't quite as severe, et cetera, et cetera.
The other aspect of bipolar two
is one that I've mentioned briefly a moment ago,
which is that it's often associated with the drops
into the depressive episode.
So people are going from manic episodes for four days or less,
then they're dropping into a depression,
going back to normal, manic again.
I do wanna point out, however,
that people who have bipolar one can, indeed,
go from manic episodes to severe
what we call major depression,
so they can oscillate like a sine wave,
really high highs, really low lows.
And very important to understand
in terms of understanding both bipolar one and bipolar two is that it's not always a sine wave.
This is really important and it's something that frankly I did not know until I started researching this episode and talking to some psychiatrist.
I should mention I've talked to several board certified psychiatrists in preparation for this episode.
I'll give some references to them and in fact some of them are going to be coming on the podcast as guests in the future for more in-depth discussion about bipolar and other psychiatric disorders.
But all the psychiatrists I spoke to confirmed what the other was saying, which was that the way that bipolar disorder can present can very tremendously between individuals.
One person might go from very high highs that last seven days or more to very low lows, bouts of depression, major depression that can last two weeks or more.
Other people are rapid cycling by way of three days manic, three days normal, three days
manic, and then dropping into three days depression.
You want to erase that picture in your mind that manic bipolar disorder is this sine wave,
this cycling up and down between mania and depression.
It can take a lot of different forms.
And again, this is a serious challenge for the psychiatrist to diagnose people because
of that fact that they're only getting a snapshot of the person unless they've known them for
some time and working with them for some time.
But this is also especially important for those of you that either have bipolar depression or
suspect that you might or that know someone with bipolar depression or suspect somebody
might have bipolar depression, aka bipolar disorder.
Because if you're noticing that somebody is very manic and then normal, well, that's a very
different picture than somebody who's going from very manic to very deep
bouts of depression.
The very manic to deep bouts of depression is easier to recognize because of the extremes
of those highs and lows.
Now this might seem somewhat obvious to all of you as I describe it.
And yet it's very important as a, frankly, a citizen of the planet, who knows other human
beings, to keep an eye out for these manic, because again, whether or not it's four days or less or whether or not it's seven days or more,
these manic episodes really are the defining criteria of bipolar disorder, aka bipolar depression.
There are a couple other key features about bipolar one and bipolar two that can allow us to get
better insight into whether or not somebody has bipolar one or bipolar two.
And that's the percentage of time that people with bipolar one versus bipolar two spend
in a manic state, a depressed state, or a symptom-free state.
This is also important to discuss because it turns out that people with genuine, diagnosed
bipolar one or bipolar two are often symptom-free, which again can make it difficult for us as
people that know them or for people that are treating people with bipolar disorder to identify
whether or not somebody is in a manic episode or a depressive episode or whether or not
they are headed into a manic or depressive episode.
So the numbers on this have been studied.
It's from a paper, actually two papers,
first author, Judge, JUDD, at all, published some years ago,
20 years ago, but the data hold up really nicely over time.
These were both published in Journal of American Medical
Association Psychiatry, so JAMA Psychiatry is a superb journal.
And basically people who have bipolar one on average
spend about 50%, it's actually 53% was the number that was eventually
converged upon, but about 50% of their time symptom-free.
That's interesting, right?
Somebody who has genuine bipolar one disorder
can spend as much as half of their life symptom-free,
sleeping normally, speaking normally, et cetera.
About 32% of the time depressed,
and when we say depressed, we mean major depression.
So severe challenges with waking up at two or three
in the morning and having trouble falling back asleep.
That's one of the defining characteristics of depression
or sleeping far too much, having a hard time
getting out of bed in the morning,
suppressed libido, suppressed motivation,
all the general symptoms of major depression,
which we'll talk about a little bit more later
and in an upcoming episode about major depression
in particular, and then about 15% of their time
in this kind of manic state or mixed manic state
where they are showing long, again, seven days
or more bouts of sleeplessness, irritability,
pressured speech, grandiosity, et cetera.
Contrast that with people who have bipolar two disorder
who are spending about half of their
time in a depressed state.
So that's interesting.
People with bipolar 2 disorder, while not always displaying depressed states or oscillations
between mania or hypomania and depressed states, they tend to be in a depressed state more
often.
And again, this is major depression.
This isn't just a little bit of a low.
This is a serious depression of their nervous system,
their mood, and as we say, their affect,
their outlook on life.
And that's one of the key distinguishing features
of major depression is that people's outlook on life
becomes very diminished in the sense
that they don't see a future.
You ask them about, you know, how's work going,
how relationships, and it's not just that
they feel that that's going poorly.
They really feel as if there's no opportunity
for those things to improve.
Those people with bipolar two
tend to be symptom free about 45% of the time.
Again, these are averages.
So about 45% of the time,
that's a considerable amount of the time.
And they tend to be in these hypomanic states
only about four or five percent of the time. Again, tend to be in these hypomanic states only about four or five
percent of the time. Again, the criteria for BP2 by polar two is these four days or less
of mania or hypomania, but only four percent of the time or five percent of the time is
a small enough sliver of the pie that is these people's existence that you can imagine
why it would be easy for them or other people to overlook
the fact that they have bipolar disorder and not major depression.
Think about it.
This is a person who, or I should say, a collection of people who are spending about half of their
time depressed, close to half, 45% of their time symptom-free, and then about 5% of their
time in a hypomanic state. So either shorten about of a high intensity mania
or hypomania that is of reduced intensity.
One of the reasons that I mentioned these percentages
of time spent in a symptom-free, depressed manic
or hypomanic state is because one of my major goals
for today's episode is that it will increase awareness
of whether or not you or somebody you know could be a coworker,
could be family member, et cetera, might be suffering from bipolar one or bipolar two.
I think it's fair to say that if somebody is suffering from bipolar one, that is likely to be revealed
or to reveal itself before too long because of the fact that people have these extended periods of
mania and mania, such an extreme state, not just for the person who's experienced it, but the way that it presents
is just so extreme and out of the ordinary.
But bipolar 2, you can imagine, could really duck under the radar of our awareness.
And you could imagine that we might just think somebody is low or depressed, especially
if that person tends to self-medicate with alcohol or other substances.
We might think, oh, whether drinking more than often, more than usual, excuse me,
or they're spending more time alone and isolating.
But then when they're in their hypomanic state, that might actually present as normal to us
because they were in such a depressed state before.
So it's very important that we dial up our awareness that we can tune our antennae
to the possibility that people out there who might appear depressed
or that we haven't heard from in a while might actually be suffering from bipolar 2 disorder.
Before we move into a in-depth discussion about the different kinds of treatments for bipolar
disorder, I'd like to touch on just a few additional aspects of what bipolar disorder can
do in terms of its negative consequences and also talk about some of the inherited risk
that is the genetic factors and the environmental factors that can contribute to bipolar disorder.
In terms of the burden, the very real emotional and occupational burden that can occur for
somebody with bipolar disorder, that's actually been studied.
There's a measure of this.
It's called global burden, which is defined as the years lost in engaging in normal
life due to some disability.
So that disability could be cancer or that disability in this case is bipolar disorder.
And basically the way this sort of study is done is that through questionnaires, I should
say quite in depth questionnaires, there's a probing for whether or not somebody has lost
to consecutive weeks or more of
interest in normal activities. Now for people who have depression that's a kind
of straightforward thing to address, right? You ask somebody, you know, when was
the last time you ate or when was the last time that you went a few days without
food or lost interest in relationships or work or sex or things of that sort
and they answer and you can figure out the amount of time that you've essentially been withdrawn from normal levels of activity for them.
With bipolar disorder, what it turns out is that the global burden of having bipolar
one and even bipolar two is massive.
In fact, having bipolar disorder sits as one of the highest risk factors for being in the top 10 of all categories of
disabilities leading to global burden.
Put in plain English, what that means is having bipolar one or bipolar due disorder is extremely
debilitating.
It really slows down one's life trajectory unless it's treated properly.
Now, the other aspect of bipolar disorder is its heritability.
And this gets into a little bit of some tricky science related to
inheritability versus the genetic contribution of a given disease.
So that might sound like the same thing.
You think, okay, genes relate to heritability,
heritability relates to genes.
But of course, everything about the way
that our nervous system works and functions and
expresses itself, healthy or otherwise, is an interaction between our genes and our environment.
And so typically the way these studies are done is you address what is the risk of somebody
having a given condition in the general population.
We talked about that before.
Bipolar disorder is a 1% of the world's population. Compare
that to people who have only major depression. So this would be repeated bouts of two weeks or more
of serious depression, not just low mood or something due to a life loss, but major depression,
which is 10 to 17% of people have major depression. Okay. They suffer from major depressive disorder, compared to bipolar disorder, which again is 1%.
Now, you can address how much of the 1%
of bipolar disorder that exists is due
to genes versus environment in a somewhat exact way.
This is never an exact science.
And the way that this is typically done is to look at
concordance, that is, the likelihood that two identical twins
will both have a given condition
as opposed to two fraternal twins,
which have more different genes than identical twins,
of course, and then two siblings
who have similar genes, of course,
but less similar than identical
or fraternal twins and so on and so forth.
So what you basically do is you evaluate the probability that two people in the general population
who are completely unrelated will have the same condition versus two people in the general
population who are very related identical twins. And what you find is that in identical twins,
if one identical twin has true major depression or major depressive disorder,
Twin has true major depression or major depressive disorder. There's a 20 to 45% chance that their identical twin will also have major depressive disorder.
Now that tells you right there that it can't all be genes.
That is not a gene for major depression per se, or if it is a gene, or a collection of
genes, that those genes are also subject to environmental influences, either prenatal within the womb or after children are born.
Now, the large range there of 20 to 45% could be due to any number of things.
It could be experimental, meaning the techniques that were used in experiments,
it could be due to regional differences, one part of the world versus another.
There are a lot of different factors.
Right now, we probably shouldn't delve into all that.
At some point, we'll probably do an episode
all about the genetics of nervous system,
heritability and heritability of features
and mental health, et cetera.
But we can compare major depression
and the heritability or the genetic concordance
between identical twins.
In major depression and bipolar disorder
and ask if one twin of an identical twin pair
has bipolar depression, what is
the likelihood that the other twin will have it?
And it turns out that number is much higher.
It's 40 to 70% likelihood or probability that if one twin has bipolar disorder, that their
identical twin will also have bipolar disorder.
So again, the total incidence of bipolar disorder in the general population is much lower than
it is for major depressions.
One percent for bipolar versus 10 to 17 percent for major depression, but the genetic component
is much higher.
40 to 70 percent for bipolar disorder versus 20 to 45 percent for major depression.
I know I'm throwing a lot of numbers out there,
but basically what this means is that researchers have been able
to take those numbers and filter them through a number
of different risk factors that are related
to early development, ask questions like if two twins
were raised separately or together
or in one part of the world versus another
or had a two
parent household versus one parent household, you know, evaluate a lot of different variables.
What they were able to discover and this has been shown again and again is that the genetic
contribution to bipolar disorder is very, very high. That is, the heritability of bipolar disorder is 85%.
Okay, so again, I want to be really clear what this means.
The total occurrence in the general population, fairly low, still serious, 1%, but fairly
low compared to other things like major depression.
However, if someone has bipolar disorder, it's very likely that they inherited some gene or sets
of genes or more accurately a susceptibility within their genes to environmental influences
that can trigger bipolar disorder.
There are a lot of different ways to discuss and to conceptualize heritability, so I want
to be very careful with the way that I'm wording this.
What this means is that people with bipolar disorder very likely have aging, or more typically
it's going to be a set of genes, that creates a susceptibility for bipolar disorder to present
itself.
Now, what environmental factors trigger or increase that susceptibility is not entirely
clear.
This always seems to center back onto the same sets of things like early life stress, trauma, etc.
Certainly those are going to exacerbate the likelihood that someone who has a genetic propensity
for bipolar disorder will express that bipolar disorder in its full array of symptomology.
But 85% while very, very high is not 100%.
Again, 85% while a very high number for heritability
is not 100% what that means is that there is no single gene
or identified gene cluster for bipolar disorder.
The reason I keep drilling into this over and over
is that I think we can confidently say
that if someone has bipolar disorder
that there was something in their genetic lineage
that led to that or that very likely led to that.
And yet it's not like eye color or some other physical feature which we can actually do
the direct, so it's called Mendelian genetics, and figure out whether or not somebody directly
inherited that gene from one parent or the other parent.
So the takeaway here is that if you have,
and I certainly have an identical twin,
or a fraternal twin, or a sibling, or a parent,
or even a cousin, or an uncle that has bipolar disorder,
in particular bipolar one,
well then you need to be on the lookout
for bipolar disorder perhaps in yourself
and for the family members of that person.
My goal within this episode up until now
has been to provide a clear
and detailed picture of bipolar disorder and its various forms. Before we start to talk about
treatments for bipolar disorder and some of the neural circuit basis for bipolar disorder,
I want to make sure that I distinguish bipolar disorder from borderline personality disorder.
We will do an entire episode or maybe even several episodes about borderline personality disorder. We will do an entire episode, or maybe even several episodes
about borderline personality disorder.
Borderline personality disorder can indeed present itself
in ways that resemble bipolar disorder and vice versa,
but there are some key distinctions that need to be made,
because it turns out that bipolar disorder
and borderline personality disorder
are quite distinct
in terms of their defining criteria. The key distinction between somebody with borderline personality
disorder and bipolar disorder is that in borderline personality disorder there can be episodes that
can resemble mania or hypomania. So periods of flights of ideas, or where people are spending money excessively
or sexually promiscuous in ways that seem manic,
or could even be a little bit manic or a lot manic.
And yet, more often than not,
there is an environmental trigger
for those manic episodes.
That is distinctly different from bipolar disorder,
where the person will have manic episodes
without any need for a trigger. There doesn't need to be a call from someone saying,
hey, let's go on vacation together, or there's something coming up this Friday that's really
exciting, or let's enter a relationship together of one former or another. The person with bipolar
disorder will have episodes of mania or episodes of major depression
without any need for an external stimulus or environmental trigger.
But the person with borderline personality disorder almost always.
Again, there's never an always in biology and psychiatry, but almost always is going to
exhibit flights of mania or depressive episodes or other types of mood shifts that are dramatic and maladaptive
in response to things that are coming in through the external environment or relationships
of some kind.
In fact, one of the defining characteristics of borderline personality disorder is this
thing that's referred to as splitting.
A good example of splitting in a person with borderline personality disorder is that they
will feel that they absolutely adore you and
want to spend all their time with you and just think the world of you.
You can do no wrong.
And in fact, they genuinely can feel that way and can genuinely think that way about you.
And then for whatever reason, it could be a perception of something that you did or
something that you said or suspicion that you're thinking something about them, they can suddenly shift or split their emotions and what's called move you from
a good object or a can do no wrong object to a bad object.
They'll suddenly decide that you are cheating on them or that you are being mean to them
or that you're insulting them or that something that you're doing is
in violation to their self worth, their wellbeing, et cetera.
And that can send them down a pathway of being very angry, very depressed, et cetera.
As I described the contour of a person with borderline personality disorder, as somebody
who splits very suddenly in response to some environmental trigger, real or perceived,
there's the risk, of course, that it makes the person with borderline
personality disorder sound like a bad person, you know, that they're very volatile. And while they
can be volatile, I want to be very careful to point out that the person with borderline personality
disorder is also suffering in this context. So while those sorts of relationships with people with
borderline personality disorder, whether they're romantic relationships
or familial or coworkers, et cetera,
can be very challenged, can be very high friction
because of the good object, bad object shifts, et cetera.
It's bi-directional, meaning the person with borderline
personality disorder, as you can imagine,
is also going through a lot of suffering.
At one moment, they feel as if someone is wonderful
and can do no wrong to them,
and they want to be so strongly affiliated with them, and then in the next moment, they feel as if someone is wonderful and can do no wrong to them and they want to be so strongly affiliated with them.
And then in the next moment, they feel as if that person is attacking them through their
actions or even through their non-actions.
So again, we will return to borderline personality disorder in a separate episode.
It's a serious disorder, both for the person that has it and for people around them.
Fortunately, there are some emerging treatments that are showing promise.
And it's a fairly
common disorder.
But it's important that we distinguish borderline personality disorder from bipolar disorder,
mostly on the basis of this need for a trigger.
Again, in bipolar disorder, there is no need for a trigger to create a manic episode or a
major depressive episode.
They just happen or they can just happen.
Whereas in borderline personality disorder, almost always,
there's an external trigger or a perception
that something happened in the environment
or that somebody is behaving a certain way
that dramatically shifts the person
with borderline personality disorder
from one mode to the next.
As we move into our discussion about the treatments for
and neural circuits underlying bipolar disorder,
I want to just nail down one more key point.
This is a very brief point, but it's perhaps the most important point, which is the highs
and lows, or we should say the highs, these manic episodes, and sometimes lows, because
again, not everybody with bipolar disorder one or two suffers from depressive episodes.
Sometimes yes, sometimes no.
In particular, bipolar two, yes, but people with bipolar one can have extreme manic episodes
and then just return to normal, as you recall.
Well, those extreme lows and or extreme highs of people with bipolar disorder impact their
lives in very negative ways.
This is essential.
And it's something that we're going to return to a little bit later when we talk about the relationship between bipolar disorder and creativity,
because it turns out that there's a quite strong association there. One that would
almost lead you to believe that being bipolar can be beneficial in certain contexts. And yet,
on whole, having bipolar disorder is extremely detrimental and challenging to the person suffering from it.
It's something that we want to keep in mind as we think about treatments
and the underlying biology.
Now I'd like to talk about some of the treatments for bipolar disorder.
In the discussion of those treatments, there's an
absolutely incredible history of the discovery of one particular treatment
that still shows great success in many patients, although
some people can't take it for reasons that we'll talk about.
And in the description of the discovery of this treatment for bipolar disorder, it also
reveals to us that sometimes treatments come to the profession of medicine and through
science in ways that precede the discovery of the underlying biology.
That's right.
Every once in a while, someone will discover a treatment for a disease without any understanding
about the underlying biological basis of that disease.
And in fact, that is the case for bipolar disorder.
And the treatment that we are referring to is lithium. Lithium, as some of you know, is on the
periodic table of elements. It is indeed a naturally occurring substance. It actually arrived on Earth
by way of star dust. Yes, we are talking about star dust on this podcast. But if you'd like to learn
more about the origins of lithium and how lithium arrived here on earth for its discovery and applications
in psychiatry.
There's a beautiful talk that exists on YouTube and we'll provide a link to this in the
show note captions.
The describes the history of lithium in terms of its interplanetary travels and arrival
on earth.
This is a talk delivered by a physicist who's expert in quantum mechanics and is expert in lithium.
And it's just wonderful talk that I can refer you to,
less on the biology in that talk,
but certainly a lot about lithium as an element.
So for those of you nerds like me
that love to know how things came to be here on the planet
in one form or another,
I'll encourage you to take a brief listen to that talk.
We are going to discuss lithiumium in the context of its
applications for treatment of bipolar disorder. And the discovery of Lithium as a treatment for bipolar disorder
is truly a miraculous story that I think everyone should know. The key player in this story is a
physician by the last name Cade. He was an Australian
physician and Cade has a very interesting story in his own right.
Cade was an Australian psychiatrist, or Australian psychiatrist, who also was a soldier.
And during World War II, after the fall of single-portage Japan, he became a prisoner of war,
and he was a prisoner of war from 1942 until 1945.
So he had some time for observation and during his imprisonment,
he observed some of his fellow inmates as going through pretty wild vacillations in mood and
energy, essentially going from manic episodes to depressed episodes or from manic to normal episodes.
And for one reason or another, we don't know why, because I couldn't find any report as to why he hypothesized this,
but he hypothesized that there was some buildup
of some chemical in these people's brains
that then they would urinate out
and that urinating out of whatever chemical was in there
would allow them to be more relaxed and not manic.
In other words, Cade hypothesized that there's a build up of a chemical in certain people's brains
that makes them manic and they urinate that chemical out.
So eventually, he got out of this prison, as we mentioned, in 1945, and he started doing
experiments in addition to seeing patients in his clinic.
And what he did is he started to take urine from people who exhibited
mania and urine from people who were not manic and he took that urine and he would inject it
into guinea pigs as an experimental model. And his general observation was that there was
something in the urine that was indeed making the guinea pigs more manic if they were injected
with urine from a manic patient. All right. The exact measures that he was taking in these guinea pigs more manic if they were injected with urine from a manic patient,
right?
The exact measures that he was taking in these guinea pigs wasn't exactly clear.
This is at a time or an urine science when you could just sort of report things a little
bit more subjectively, although there were still numbers and statistics.
There's a little bit more of like case studies and descriptions, but it turns out that even
though that all seems a little bit loose, it led to some incredible and still important
discoveries for psychiatric health.
So what he figured out was that the urine from manic patients seemed to be more toxic
for these guinea pigs.
And he also knew that there are two toxic substances in urine, urea and uric acid. So he was able to separate the urea and uric acid
from people with mania and patients that did not have mania. And he figured out that the urea
was the same in both these mentally ill, manic patients and the non-manic patients. So it did not
seem that urea was the compound that was creating these manic episodes or related
to manic episodes or held the toxicity.
So instead he focused on the uric acid.
Now in order to put the uric acid into solution so that he could inject it into these guinea pigs,
he had to try a number of different compounds in order to dilute it.
It just so happens that, and you, chemists will be familiar with this,
but there's certain things that just don't go into solution easily.
You put the powder in a vial,
you add some water or a saline or another solution,
mix it up and the powder stays suspended in there.
It just doesn't, it doesn't actually ever become a clear liquid
that you can inject.
So in order to try injecting different strengths of uric acid,
he ended up using lithium to assist in the dilution and lithium worked. So what he basically was doing,
again, for eukemis, is he was taking uric acid, he was adding lithium and making a solution of
lithium urate. Okay? This is a lot of details, but this is important because what he eventually found is that
when he diluted the uric acid with lithium and created lithium-urate, lithium-urate could actually
calm down these guinea pigs that were injected with the toxic urea. He also found that lithium-urate
had a generally calming effect on these guinea pigs. So now we're really off in crazy territory.
If you're right, we're talking about urine from patients that's separating out urea and uric acid.
We're adding lithium to the uric acid.
We're injecting this in the guinea pigs.
This is getting pretty wild and pretty weird.
But this is medicine and from time to time, this is medicine and science.
Cade was a good scientist in addition to being a good physician.
And by good scientists, I mean that he did control experiments.
Here he was injecting lithium urate into animals and seeing an effect.
But he knew that that solution of lithium urate contained not just the uric acid, but it also
contained lithium.
And so he quite appropriately asked, maybe the lithium alone is having this calming effect
on these guinea pigs.
And indeed that was the case.
When he did the proper control experiment and injected only lithium solution into these
guinea pigs, they calmed down.
From there, he in sort of 1940 style medicine,
this would not happen now,
he very quickly moved from that animal model
into human patients and started injecting human patients
with lithium or providing lithium orally to those patients.
And lo and behold, found an absolutely profound
and positive effect of lithium in reducing symptoms of mania.
And as all good physician scientists do, he wrote up his results. And he wrote it up in a paper
entitled lithium salts in the treatment of psychotic excitement. Okay, back then they didn't
call it mania. They called it psychotic excitement. This is a paper that was published September 3rd, 1949 in the Medical Journal of Australia.
We will provide a link to this study as now a classic study in the field of psychiatry.
It's a really wonderful paper to read, and actually I encourage people, even if you're
not a scientist or a clinician, to just take a quick look at the second page in this paper
that we've made available to you,
where he describes each of the various case studies or the individuals that he looked
at.
I'm not going to read these in detail now because it would take a lot of unnecessary time.
But things like case seven, MC, age 40 years old, suffering from manic recurrent mania.
This episode, he'd been excited, restless and violent for over two months and was interfering so often that had be confined to a single room during the
day. This is very debilitating what we now know to be bipolar depression. He commenced
taking lithium citrate 20 grains, that's a measure of the amount of lithium three times
a day. In four days he was distinctly quieter and by February 13th, 1949 appeared practically normal.
He continued well and on February 20th, 1949, the dose of citrate was reduced to 10 grains,
et cetera, et cetera.
He left the hospital.
There are numerous descriptions of this sort within this paper, including some descriptions
of patients that did not see such success, and including some descriptions of patients
that suffered from some negative side effects.
So that's important to point out as well.
But it's an absolutely wonderful paper.
And it's an absolutely wonderful voyage into the history of psychiatry right down to the
discussion where in just three short paragraphs, Cade really lays out the case for why lithium
is such an important discovery in the treatment of what at that time they
were calling psychotic excitement and what we now know to be manic bipolar depression.
Lithium, I should mention, has a number of important features, but also a number of important side
effects that need to be considered. First of all, it does have a certain toxicity, and so levels of
lithium in the blood need to be monitored extremely carefully.
So it's not the sort of thing that people can just take it a given dose and every patient
responds the same.
There's a lot of oversight and a lot of blood tests that have to be done, especially in
the first three months of lithium treatment.
I should mention that lithium treatment is still used to some great degree of success in
many, not all people suffering from bipolar depression or bipolar
disorder rather, but there are a number of important things that happen between 1949 and
present day that prevented lithium from reaching patients that really needed it.
And that all can be summarized in two or three short sentences, basically by virtue of the
fact that lithium
is a naturally occurring element, it could not be patented.
And as a consequence of that, there wasn't a lot of potential profit for drug companies
to produce lithium.
In fact, still to this day, it's very low cost.
And still to this day, no one really owns the patent for lithium in its purest form.
So that made it unattractive.
It turns out that the FDA in the United States
didn't allow lithium to be used as a treatment
for manic bipolar disorder until 1970.
So we're talking about a full 21 years
from the publication of this paper by Kate
and the Medical Journal of Australia showing
quite beautifully the great potential and use of lithium for quelling
the symptoms of bipolar disorder until the first patients in the United States were starting
to access lithium regularly.
And nowadays, of course, lithium is available, but still not able to be patented because
it's element number three on the periodic table.
It's naturally occurring.
It's not literally falling down from the stars at star dust and going into pill form, but rather it can be synthesized in laboratories,
but it is available. It does show not only great potential in many patients, but great application
in many patients, despite its side effects. So lithium really stands as this golden example
of a treatment that works, at least in many individuals,
prior to an understanding of the biological basis of the disease for which that treatment
is needed.
Now with that said, scientists and clinicians have been quite rigorous in trying to understand
why and how lithium works in order to understand the why and how of bipolar disorder.
This is the way that proper medicine and science is done,
even if there's an excellent treatment for something.
It's important to understand why that treatment works,
because first of all, not everyone responds
to that treatment, second of all,
scientists and physicians understand that
just because we have one treatment that works,
if it has any side effects at all,
there is the possibility for better treatments.
So it's not just about trying to bypass a drug that doesn't make much money for drug companies.
I know a lot of people think in those terms, they think, oh, well, you know, there's this
continued search for better treatments for bipolar disorder, even though lithium works because
lithium doesn't allow drug companies to make much money.
That's not really the case.
The fact of the matter is, is that the toxicity, some of the other issues that are created with lithium, the fact that people need the ongoing blood testing, etc.,
really stimulates the need, really an urgent need for new and better treatments for bipolar
disorder and only by understanding how lithium works at the cellar level, at the neural circuit
level, etc. do we really stand to find those new discoveries? If you were to do a literature search on the actions and mechanisms of lithium in terms
of how it can calm people down and reduce their manic episodes, you would find an enormous
array of papers, literally thousands of scientific studies in animals and in humans, which, for
instance, will tell you that lithium treatment will increase so-called
BDNF, brain-derived, neutrophic factor.
BDNF is often talked about in the context of neuroplasticity, the brain and nervous system's ability
to change in response to experience.
And indeed, it does seem that ingesting lithium increases BDNF.
BDNF is what we call permissive for neuroplasticity.
It doesn't create specific changes in the brain, meaning it's not going to make your memory
better or your coordination better or your emotional state better per se. What BDNF does
is it permits the neurons, the nerve cells, and their connections in the brain to be more likely to change
if the proper environmental conditions are met.
That is, BDNF creates a kind of buoyancy to neuroplasticity.
It opens the gates to neuroplasticity.
So lithium does increase BDNF.
We'll talk about why that's important in the context of the neural circuits involved
with bipolar disorder in a few minutes.
It also seems to be a potent anti-inflammatory.
Inflammation is one of those words that's thrown around extensively nowadays, especially
on social media, and especially as it relates to any health condition.
It's like inflammation, inflammation, inflammation.
Always seems to be discussed in the context of inflammation being bad, but I do want to
point out that inflammation is a natural adaptive response to physical injury
to a cell or organ or tissue of any kind.
Inflammation is the basis by which adaptations occur
to exercise.
So for instance, you were to weight train
and use a heavier than normal weights
and do a set to failure or create some little micro-terrorism
the muscle that are healthy in the sense that they would create adaptations and make that muscle stronger, maybe you
can grow that muscle.
There's an inflammatory response associated with that, that is critical to the positive
adaptation.
So inflammation isn't always bad, although excessive or as we say runaway inflammation
is bad.
Lithium seems to be able to suppress inflammation and importantly,
it can suppress inflammation in neural tissues and within the brain in particular. That is
important. And we will return to that and why it's important in a little bit. The other
thing about lithium is that lithium is neuroprotective. That is, it can prevent neurons from dying
under certain conditions. Why would
neurons die? Well, there are a lot of reasons why neurons can die. There can be a physical
insult to the neurons. You can get hit really hard in the head, a bullet, you know, God
forbid, can enter the skull and kill neurons. There are a lot of reasons why neurons can
die. Neuroprotection is a situation in which a neuron is given some sort of chemical or physical resiliency
that allows it to suffer an insult and yet bounce back.
So it's very similar to the way that we think about psychological resiliency.
Neuro protection is an ability for neurons to be better able to handle stress of different
kinds, in particular, excitotoxicity.
There's a phenomenon in bipolar disorder and a lot of other psychiatric conditions in which
hyperactivity of certain brain areas actually starts to kill off neurons.
Hyperactivity doesn't always do this, but it turns out that if certain brain circuits are too active for too long,
some of the chemicals associated with neuronal activity, things like calcium and neurotransmitters like glutamate can actually kill the very neurons that are active.
So it seems that lithium can prevent some of that neurotoxicity.
Now this turns out to be particularly important for this discussion about bipolar disorder
and the neural circuit bases with bipolar disorder.
Because if we are to just take a step back and ask what's different in the brains of people with bipolar disorder,
there are some very interesting answers that start to emerge. There are basically two main neural circuits that are present in normal individuals.
I say normal, I say that respectfully to the people with bipolar disorder by referring
to people who do not suffer from manic episodes or from manic depression.
There are circuits that are present in people with bipolar disorder and In people that do not suffer from bipolar disorder
Both of those circuits do the same thing in
Both sets of individuals and yet in people with bipolar disorder
There seems to be an
Atrophy or a removal of certain neural connections over time that leads to a situation in which people with bipolar disorder become very
poor at registering their own internal state, in particular, their emotional states and
their somatic states.
What we're referring to here is something called interoception.
I've talked about this a little bit on the Hubertman Lab podcast before, but there are two modes
of perception.
Perception, of course, is a attention to something that's happening in
our environment or to us on or within our body. Exter reception is literally an attention
to things that are happening beyond the confines of our skin. So seeing that person's face
over there or seeing that color of leaf over there or hearing a sound over to my left, that
is extra reception, perception of things beyond the confines of one's skin.
Then there's interoception, which is perception of things
that are happening internally.
How full does my gut feel?
How fast is my heart beating?
Some people can measure that quite accurately,
just by thinking about it, other people can't.
How happy am I?
How sad am I?
How energetic am I?
How lethargic am I, et cetera, et cetera.
So we are always existing in a balance between exter reception and interception, but as it
turns out, people with bipolar disorder over time, and especially into the second and
third decade of having bipolar disorder, seem to have progressively diminished levels
of interception.
And that very likely is important
in their inability to register, for instance, that, wow, they are talking at an excessive rate,
or they haven't slept in five or even ten days, or they haven't eaten in a long period of time.
This atrophy of neural circuits for interoception is starting to emerge as one of the defining neural circuit
characteristics or underpinnings of bipolar. Now, I bridge to this conversation about neural circuits
from the statement that lithium can protect against some of the neurotoxic effects of neural circuits
being very active. Now, this can get a little bit complicated, but I promise I'm going to make it clear for any of you that are watching and or listening.
The reality is that people with bipolar depression very likely have a hyperactivity. That is an increased level of activity in certain circuits within the brain early in the expression of their disease.
And that typically, as I mentioned earlier, sets in around the early 20s, although sometimes that can be even earlier
in the teens and so forth.
But that hyperactivity, we think,
leads to a toxicity, an excitotoxicity,
of certain elements of the neural circuits
that are responsible for interoception.
In other words, the overuse of certain circuits
can lead to a diminishing, an atrophy, or even a death of certain elements within lead to diminishing an atrophy or even a
death of certain elements within those circuits.
And it appears that lithium through its anti-inflammatory and neuroprotective effects and through its
ability to increase BDNF very likely protects us against some of that atrophy of those circuits
for interoception.
So this isn't a case in which people with bipolar
have a neural circuit or lack a neural circuit
and people without bipolar are the opposite.
This is a case in which everyone more or less starts out
the same, but it seems that there's a hyperactivity
of certain neural circuits in people with bipolar disorder
that over time actually causes those circuits to diminish.
Now this is very important because some of the more recent
longitudinal studies
do in brain imaging on people with bipolar disorder and those without, and doing that over time
in patients starting as early as their teens, but into their 20s and 30s, reveals just that,
that there can be hyperactivity of circuits early on, but then hypoe reduced activity of
those very same circuits at a time five or 10 years later. Again, this speaks to the complicated nature
of bipolar disorder and the complicated nature
of psychiatry and linking specific psychiatric disorders
to neural circuits in general.
Because if you have a situation in which,
in one disease, let's just hypothesize here for a second
that for instance, in certain forms of schizophrenia,
there's elevated dopamine and where we to just reduce the amount of dopamine that they would receive relief from those
schizophrenic symptoms. Well, that's all pretty straightforward on the face of it. But in this
situation with bipolar disorder, what we're talking about is hyperactivity, too much activity,
leading to hypoeactivity through death of those very circuits. And so now you can especially appreciate
why when the patient shows up to the appreciate why when the patient shows up to
the psychiatrist or when the psychiatrist shows up to the patient in the total course of their
disease is going to be very important. And then layer on top of that, the complexity of the
fact that the very defining characteristic of bipolar disorder is that there are oscillations in
mood. So now we need to think about treatments not just for the manic episodes, but also treatments
for the depressive episodes.
And that's in fact, what psychiatrists do turns out that they apply different treatments
or combinations of treatments for patients that are in manic episodes versus depressive
episodes.
And they have to infer all that from discussions.
Again, just exchange of words, depending on when that person walked into their office,
where they are in terms of manic
episodes, no symptomology or depressive symptomology, and whether or not they've had that symptomology
for an extended period of time. And then just to make the situation even more complicated,
the very circuits that atrophy that start to wane and disappear in people with bipolar disorder
are the circuits for interoception, for understanding of what's going on in one's own body.
So you can imagine if you sit down and ask somebody, well, how long has it been since
you slept, that person may genuinely not know.
Or if you ask the very depressed person, how depressed are you?
That person may not be able to articulate that.
So fortunately, there are solutions to this.
And the solution is that more often than
not, the accurate understanding of whether or not someone has bipolar depression or not,
and what stage of the illness they might be in or not, is going to depend on the reports
of people around them and not the patient themselves.
Hence, the importance of having a rather detailed and admittedly a rather intense discussion
about the symptomology of bipolar disorder so that you can have an understanding of the
people around you and have an eye and an ear to whether or not those people might be suffering
from bipolar and if so at what stage of the disease they might happen to be at.
Now I'd like to talk a little bit more about what is known about the neural circuits that
lead to the manic states as well as the depressive states, but mainly the manic states of bipolar
disorder.
We already discussed the fact that interreception, registering of one's own internal emotions
in bodily states is diminished in people with bipolar disorder.
But we haven't really talked about the neural circuits that are responsible for that lack
of recognition.
For that reason, I'd like to point out a paper,
this is a fairly recent paper, just came out this year,
but it's an excellent one,
looking at the changes over time in neural circuitry
in people with high genetic risk for bipolar disorder,
and in particular in young people.
And studies of this sort are rare,
but are exceedingly important because of the fact
that they track individuals over time. The title of this paper is rare, but are exceedingly important because of the fact that they track
individuals over time.
The title of this paper is Longitudinal Changes in Structural Connectivity in Young People
at High Genetic Risk for Bipolar Disorder.
We will provide a link to this study in the show note captions.
There are a lot of data in this paper, in particular neuroimaging data, and it's quite extensive
in terms of analyzing
the so-called conic tomics.
You've probably heard of gene nomics,
which is the analysis of genes
and their display in different individuals
or different animals, et cetera.
You have proteomics, which is the display
of or the existence of different proteins.
So omics is a big thing now inside.
So you kind of throw omics behind anything
and it becomes its own Wikipedia page,
which means it becomes its own thing.
So to speak, I say that only partially ingest.
Nonetheless, connectomics is the analysis of connections between different neurons and neural circuit elements.
And what this paper really showed by analyzing the connectomics of neural circuits in the brains of many different people with different
categories of and on set of and
severity of
bipolar disorder as well as controls in different age groups, etc.
is that
people who are a particularly high risk for having bipolar disorder or that have full-blown
bipolar disorder have
deficits and actually reductions in the amount of connectivity between what are called the
Priddle brain regions and the limbic system. Now the limbic system I've talked about before in this podcast if you're not familiar with it
I'll explain what it is in a moment
It's simply a collection of brain structures not one brain structure, but a collection of brain structures that generally are responsible for shifting the overall state that we're
in from states of more relaxed and calm to states of more alert and focused.
The limbic system is intimately related to the so-called autonomic nervous system, which
regulates our sleep wake cycles and the number of other things like our digestion, et cetera,
our level of hunger and on and on.
So the limbic system is really kind of like a volume control
or as nerd scientists like to say,
a kind of game control on the overall level
or amplitude of alertness or calmness.
In fact, if we're very, very calm,
we are sleep or even more calm, we can be in a coma.
If we are very alert, we can be wide awake
and ready to work and run, et cetera.
Or if we are very, very, very alert
by way of limbic autonomic interactions,
well, then we can be in anxiety,
we can be in full-blown panic attack,
or we can be in nania.
We can have so much energy that we feel like
we don't need to sleep.
And in fact, disruptions in the circuitry really seems to be what's going on in people
who have bipolar disorder.
Now, if disruptions in the circuitry are present in the limbic system, that doesn't necessarily
mean that the limbic system is at fault.
Because the way that neural circuits work is that different brain areas are talking to
one another through electrical chemical signaling and they are regulating one another.
And what this paper really tells us is that their elements within the parietal lobe, which
is a kind of a section of the brain that sits off to the side, it's not really off to the side,
but in neuroinatomical nomenclature, the parietal lobe is connected in two ways bidirectionally.
So parietal lobe is connecting to limbic system,
and limbic system is connecting to pridele lobe.
And in people with bipolar disorder,
it seems that the pridele lobe is able to exert
less top-down control,
that is less suppression of certain elements
of the limbic system,
which at least right now is leading researchers
to hypothesize that the limbic system is sort of
revving at
higher levels.
It's kind of like RPM in your cars or redlining at times and for durations that are inappropriate
or at least abnormal.
So we have two major sets of neural circuit deficits or changes in people with bipolar.
Their lack of internal awareness is reduced and that turns out to be by way of neural structures like the insula, which is a brain region that is connected in a very
direct way to our somatocensory cortex, so the part of our cortex that registers how we feel
literally, sense of touch, and internal state. So those circuits, excuse me, those, for those of you listening, I just bumped the microphone.
Excuse me. Those circuits are disrupted in people with bipolar and the top down control, the kind of accelerator and break on our overall levels of energy are also disrupted. Now,
that's all fine and good because, well, it's true, at least according to what the data at this
point in time tell us, there may be new discoveries to come, but that all seems to be the case, but it doesn't
tell us how to modulate or change that circuitry.
It also does and tell us how something like lithium can actually benefit a large number
of patients or how a good number of the other treatments for bipolar disorder, which we'll
talk about going forward, can benefit patients
with bipolar.
So it appears that lithium is exerting its positive effects on bipolar depression treatment,
at least in part by preventing the loss of certain neural circuits, namely the neural circuits
for interreception and the top down control over the limbic system.
Now it turns out to be examining lithium's effects at an even more reductionist level.
We can gain really important
insight into what's going on in bipolar depression and some of the other treatments for bipolar
depression, including behavioral treatments, things like transcranio-magnetic stimulation
and even some of the more natural or so-called nutraceutical treatments, including things
like high dose omega-3 supplementation, which we're going to talk about extensively.
Now in order to understand what we're going to talk about next, it's important that everybody
understand a key concept of neuroplasticity.
And this is a key concept regardless of whether or not one is talking about bipolar depression.
In fact, it's something I think everybody, every citizen of Earth should know about.
And that's called homeostatic plasticity.
Homeostatic plasticity is a particular form
of neuroplasticity in which if a neural circuit is overactive for a period of time, there
are changes that occur at the cellar level that lead to a balance or a homostatic regulation
of that circuit so that it's no longer overactive. Conversely, if a neural circuit is underactive
for a period of time, certain changes happen
within the cells of that circuit to ramp up their activity
or make them more likely to be active.
And whether or not a neural circuit and the neurons within it
become more active or less active
in the context of homeostatic plasticity,
largely depends on one mechanism.
And it's a beautiful mechanism that I'll make very clear to you right now, even if you
don't have a background in biology.
Neurons communicate with one another by releasing so-called neurotransmitters, which are just chemicals.
Those neurotransmitters are vomited out, they're not actually vomited, but they're spit out
into the so-called synaptic cleft often called the synapse.
The synapse is just a little gap between neurons.
And when they are released into the synapses,
they don't just stay there.
They actually park or bind to receptors
on what's called the post-synaptic neuron.
And depending on how many receptors they bind to
and how many receptors are available, et cetera,
they can have a greater or lesser effect
on the post-synaptic neuron.
This scenario of neurotransmitters being released into synapses
then binding to receptors on post-synaptic neurons and influencing the electrical
excitability of those post-synaptic neurons, sit central to not just the treatment of bipolar
disorder, but to all treatments of all psychiatric conditions and indeed to things like neuropathic
pain as well. For example, the so-called SSRIs, prozags, oloft, and others, et cetera, stands for selective
serotonin reuptake inhibitor.
What does that mean?
Well, serotonin is a neurotransmitter.
It's actually a neuromodular that's released into the synapse.
And then the SSRI, the selective serotonin reuptake inhibitor, allows more of that serotonin
to sit within the synapse for longer, right?
It's a reuptake inhibitor.
It prevents reuptake by the presynaptic neuron. And that serotonin, therefore, can park in or dock
in the receptors, as it's called, of the postynaptic neuron in greater numbers and have a greater
impact on that postynaptic neuron. So the drugs that are used to treat depression or other
things of that sort, things like SSRIs,
work by changing the availability of neurotransmitter in the synapse.
Other things like MAO inhibitors, monoamine, oxase inhibitors work a different way.
They inhibit the enzyme.
Anytime you hear ASE in biology, it's very likely an enzyme which breaks things down.
So MAO inhibitors prevent the breakdown, not the reuptake, but the breakdown of neurotransmitter,
and therefore allow more neurotransmitter to be available in the synapse and influence
the post-ynaptic cell.
Homostatic plasticity is a form of neuroplasticity in which overall circuits can become much
more excitable or much less excitable by the addition
of more receptors in the post-anaptic neuron or by the removal of more receptors from the post-anaptic
neuron. And the way this happens is just beautiful. It was first discovered in the visual system
and the person primarily responsible for the discovery of homeostatic plasticity, although there
are several, is a one by the name of Gina Tururgiano, she's a professor at Brandeis University.
And what the Turgiano Laboratory showed was that, for instance, if we are in the dark
for a long period of time, literally, and we're not seen much for a long period of time,
there's an increase in the number of receptors in the post-anaptic neurons, so that a smaller
amount of light and excitability within the visual system can lead to greater amounts of activity in the visual system.
Conversely, if there's an overactivity or an increase in activity in the visual system for some period of time,
then a number of receptors in the post-anaptic neuron
are removed from that post-anaptic neuron surface,
making any neurotransmitter that's available,
only able to bind the receptors that
are left and have less of an influence on those cells.
In other words, keeping a circuit in so-called homeostatic balance in a particular range
of excitability.
Now, well, that's a mouthful and an earful and a conceptful, I don't know if a conceptful
is a word, but in any case, that's a lot to think about.
But all you need to know is that if a neural circuit is very active for a period of time,
in normal individuals, there will be a reduction in the amount of activity by way of removing
receptors that buy neurotransmitter.
Whereas if a neural circuit is very quiet, it's not activated for a period of time.
Maybe your leg is in a cast, for instance, and you're not activating your quadricep and
calves very much.
Well, when that cast comes off, sure, the muscle might be atrophied, but the nerves that connect
to that muscle are actually in a position to influence that muscle even more once you start
using that muscle or those muscles because whatever neurotransmitter is released now has the
opportunity to bind to more receptors in that case in muscle or in the case of brain
circuits in post-enaptic neurons.
So homestatic plasticity is this beautiful balancing mechanism that makes sure that neural
circuits are never too active nor too quiet for too long.
And in a beautiful display of how treatments can lead to a better understanding of biology, which can lead to the discovery
of even better treatments, lithium, and another compound, which we'll talk about ketamine,
seem to exert their actions largely through effects on homeostatic neuroplasticity.
There's a wonderful paper that describes all the nitty gritty of this.
Certainly most people listening, I'm guessing, are not going to be interested in all this detail. But for those of you that
you are and you want to delve deep into this, this paper was published in neuron, cell
press journal, excellent journal. It's titled targeting homeostatic plasticity for the
treatment of mood disorders. And there's one particular figure in this paper that I'll
just describe to you in which measurements were
made from neurons and the number of receptors in those neurons.
It's done somewhat indirectly through a method that's detailed and neuroscientists are
familiar with.
Basically, what it measures is how excited a given neuron is, electrically excited, a
given neuron is, to a given amount of neurotransmitter.
Okay?
So the amount of neurotransmitter that's vomited onto a neuron is essentially kept constant. And then the response of the post-anaptic neuron is measured. So it can
be of one level or higher or lower depending on homeostatic plasticity. And what this paper shows
and what's been shown over and over again is that when neurons are exposed to lithium for a period of time, there is a reduction in
the excitability of the post-synaptic neuron.
That is neurons within the brain become less excitable over time if lithium is present,
whereas ketamine, which is now a common FDA approved, at least in the US, it's approved
for the treatment of major depression,
ketamine does the opposite.
Ketamine seems to increase the number of receptors in the post-anaptic neuron and lead
to greater levels of excitability and electrical activity within neural circuits to a given
fixed amount of neurotransmitter.
So this is super interesting because what it means is that lithium is causing circuits
to be less active.
Ketamine is causing circuits to be less active. Cetamine is causing circuits to be more active.
And we know from excellent clinical data, now that ketamine seems to be a very effective
treatment for major depression and for the major depressive episodes of people that suffer
from bipolar depression that includes these major depressive episodes of two weeks or
longer of suppressed mood, appetite, sleep issues, etc. Now, the key thing about ketamine that's often not
discussed is that while its effects are very potent, they are transient. So one major drawback
to ketamine therapy for depression is that it has to be done repeatedly. And how repeatedly,
or how often rather, depends, of course, on a discussion between the psychiatrist
and the patient.
This is not something to cowboy on your own.
I know that, and many of you are probably familiar with the fact that ketamine also is
abused recreationally.
It is a so-called NMDA and methyl deaspertate receptor antagonist.
It blocks the very receptor that's responsible
for neuroplasticity, for changes in neural circuits.
It also changes excitability in neurons
as I just described.
So ketamine is a very potent chemical
that has been shown over and over again,
and is now FDA approved for the treatment
of major depression, but its effects seem to be transient.
Lithium, as I described earlier,
seems to reduce the manic episodes
or the intensity of manic episodes
in symptomology and people with bipolar disorder.
It's doing that through neuroprotection.
So protecting neural circuits from dying away
that initially are overactive
and that overactivity causing a cytotexicity.
It blocks that excited toxicity, we believe.
And it seems to do that in part by diminishing the amount
of activity in those circuits. So this is a beautiful mechanistic story. And it's the
sort of story that you'd love to have for a great number of psychiatric illnesses. And
fortunately, we have for bipolar disorder, overactivity of a given circuit eventually leads
a neuro toxicity, excuse me. Lithium is preventing that neurotoxicity by reducing
the number of receptors in certain elements within those circuits, so so-called homeostatic scaling.
It's down-regulating the number of receptors leading to less excitability and preventing we think
excitotoxicity. And in that sense, you can see exactly why it's important to get lithium treatment
in there early for
people with bipolar disorder.
Kedamine as a treatment for major depression seems to be effective, but transient, and you
can also see why it would be important not just to reduce the manic episodes for people
with bipolar disorder, but to also treat the depressive episodes.
So this is a key feature of the treatment for bipolar depression and for bipolar disorder.
There needs to be treatment both of the mania and of the depressive episodes if they're
present.
Unfortunately, there are excellent drugs to do that.
And I should mention that ketamine and lithium are just two of the drugs within the kit that
psychiatrists have had access to.
There are many things, olandzepines, and number of different, including, close-upine.
Close-upine is an anti-psychotic, which is commonly prescribed to, as a sedative in some cases,
that allows people in manic episodes to sleep. It's classically described as so-called dopamine
receptor for antagonist, although it does other things as well. Close-upine has a number of side-effect
features related to white blood cell and things of that sort
that require careful monitoring.
So there are an enormous number now.
Literally dozens and dozens of different drugs
each designed to target either the manic phase,
the depressive phase or some what we call acute
sort of early phases versus ongoing treatments.
This is a vast galaxy of drug treatments that really should be navigated.
I should say absolutely should be navigated by a board certified psychiatrist and of course
in close discussion with both the person suffering from bipolar disorder, but also ideally
the family members of the person suffering from bipolar disorder. But I think, at least up until now,
we've focused on the two major pathways for treatment,
lithium and ketamine.
And we've talked about why lithium and ketamine work,
that they're working on opposite ends
of this homeostatic scaling.
We talked a bit about the circuits that are involved
in generating what we think are the manic symptomology
and the lack of interception, why people can just persist and
staying awake, awake, awake, not eating, etc. Now you have in mind
how all that is put together, and I think you have in mind some of the
well-demonstrated treatments for the different component parts of bipolar disorder,
which now I'm hoping you're also well-versed in based on our early early
discussion of what constitutes bipolar one and bipolar two
Now I would like to also talk about some of the not so typical therapeutics for bipolar disorder and
also point to the things that have been tried and failed
for
successful treatment of bipolar disorder because some of those things are
often talked about and
Suggested especially in online
communities. And while it's not clear that any of them are particularly hazardous on their own,
although some of them do carry some hazards, I do think it's important because of the critical
time-sensitive nature of bipolar disorder and the urgency of getting treatments early to try and
prevent some of the longer-lasting neural circuit changes, that if people can avoid some of the less effective or demonstrated to be
ineffective treatments, that they stand to combat bipolar disorder much more successfully.
First of all, a key point about drug therapies versus non-drug therapies or talk therapies.
Without question, drug therapies are going to be most effective when done also with talk therapies. Without question, drug therapies are going to be most effective when done also
with talk therapies. And we'll talk about which talk therapies have been demonstrated to be
most effective. There is some argument about what I'm about to say next, but in general,
most psychiatrists will tell you it's certainly the ones I spoken to have told me that talk therapy on its own is rarely
if ever effective for bipolar depression and bipolar disorder, whether that's BP1 or
BP2.
That's just the reality of it.
Contrast that with our discussion about obsessive-compulsive disorder, which we talked about a few
episodes ago.
You haven't seen that episode.
We have an in-depth episode all about OCD and obsessive
compulsive personality disorder. There it seems that drug therapies and talk therapies can be done
independently or in combination. As expected, combined drug and talk therapies are more effective
there than either one alone, but there are pretty impressive effects of talk therapy alone provided
that they're initiated at the right time and it's the right form of talk therapy.
That's OCD, but in terms of bipolar disorder, it really seems that the drug therapies are
necessary, at least in most all cases.
That said,
talk therapies are terrific augment or support for those drug therapies and sometimes can allow people to take lower doses of those drug therapies,
which turns out to be important because of the side effect profiles of a lot
of drug therapies and sometimes the cost as well.
I guess we can think of cost just as another side effect really.
There are both established and more novel forms of talk therapy being used again in concert
with drug treatments for bipolar disorder.
Cognitive behavioral therapy is the one that seems to be best, at least by way of the
statistics and papers that exist.
It's also the one that's been explored the most.
So one of the reasons why it's often considered the most popular or effective is because
it's also been around longer and it's been explored the most.
Cognitive behavioral therapy in general is a progressive exposure of the patient in a very
controlled way in a clinical setting to
some of the triggers or the conditions that would exacerbate bipolar disorder.
Now earlier I said borderline personality disorder has all these triggers and triggered elements
from the external environment whereas bipolar disorder does not.
That's still true, but it is the case that somebody with bipolar can have worse symptoms if life conditions get
worse and more stressful.
So cognitive behavioral therapy, the discussion about, and sometimes the direct exposure to
anxiety-provoking elements of life can be very helpful for adjusting the responses to those
otherwise triggering events and sometimes making the drug treatments more effective even at lower doses.
There are also forms of therapy including family-focused therapy, which is especially important
in terms of bipolar disorder because family members provided that they are not themselves
in a manic episode due to the close heritability of bipolar disorder.
But family members can often be excellent windows
into whether or not somebody is doing well
or poorly or is veering toward
or is emerging from a manic or depressive episode
because they understand that person.
They have a lot of data.
It could be purely subjective data,
but they have a lot of exposure
to how long or well somebody's been sleeping
or eating, et cetera.
So family focus therapy involves other members of the person suffering from bipolar disorders
family, as well as conversations about family members in a way that helps patients with
bipolar disorder navigate not just through manic episodes, impressive episodes, but
start to learn to predict what are the conditions, psychological, physical, and otherwise that
can trigger bipolar episodes.
And then there's a category of therapy called interpersonal and social rhythm therapy.
This is deserving of its own entire episode, really.
Interpersonal and social rhythm therapy is sort of an expansion on family-focused therapy,
although it's distinct in certain ways as well.
And really focuses on how people are relating to others in their life and in the workplace
and in the school environment and also within the family, et cetera.
And I should say that a overall theme that's emerging in psychiatry and psychology is to
start wherever possible to incorporate more of the social aspects and the interpersonal
aspects. In other words, not just talking to and examining a patient as one biological system, one
nervous system, one set of chemicals and one life, but rather a set of chemicals, neural
circuits, and a life that's embedded in the chemicals and neural circuits and lives of
other people.
Just by way of example, you can imagine that if somebody is in a very healthy relationship
or a very abusive relationship, that that's going to strongly impact the outcomes of manic episodes. You can imagine
that if the financial situation is one in which people can recover from manic episodes,
I didn't mention this earlier, but I should have, forgive me, that oftentimes people who are in
a manic episode will go out and spend immense amounts of money that they simply cannot afford to lose.
And then the depressive episodes that, in many cases, follow are made far worse by the
financial anxiety and the financial stress that results from those manic episodes of spending,
et cetera.
And then, of course, this carries over to sexual promiscuity where people might be dealing
with unwanted pregnancy or STIs or very
fractured interpersonal dynamics with existing or new relationships.
I mean, you can imagine how these manic episodes, as well as the depressive episodes, can
really wick out into an enormous amount of destruction, which brings us back to the
initial criteria of BP1 and BP2, is that these manic episodes are not a good thing.
These depressive episodes are not a good thing.
They create this sense of euphoria in the person experiencing mania, or they create this
sense that anything is possible, but at the end of the day, and actually every day, these
episodes are quite maladaptive.
They really destroy people's lives, and it's not just the life of the person that's suffering from bipolar disorder.
And so hence, cognitive behavioral therapy, family focused therapy, and interpersonal and social rhythm therapies are the primary three talk therapies that are most often combined with drug therapies in order to try and really reduce the harm.
It's really all about harm reduction from manic episodes and depressive episodes.
One very exciting and emerging treatment
that does show great promise,
and in some cases great outcomes for bipolar disorder
is believe it or not, electric shock therapy.
Electric shock therapy may sound barbaric,
and in fact, it tends to look barbaric
although this is done in the controlled setting of a hospital.
If any of you have seen one flu over the Cuckus nest, I think the final scene or near final
scene in that movie was Jack Nicholson with the sort of bite protector in his mouth and you know,
getting electric shock therapy. And it's as the name suggests, it's a kind of inducing a global
seizure, either low level or grand mall type seizure in the patient's brain and
nervous system.
You might ask, well, why would one want to do that?
Well, it turns out that this is a well established and in many cases, very effective treatment
for major depression.
Electric shock therapy is generally used for treatment resistant depression.
So these are people that have no positive response or ongoing positive response to drug
therapies or other therapies.
Electric shock therapy is thought to work primarily by stimulating the massive and indiscriminate
release of things like serotonin, dopamine, acetylcholine, you know, a huge variety of neuromodulators
as well as things like BDNF, brain derived natrophic factor, which then allows
neuroplasticity to take place, again, BDNF
being permissive for neuroplasticity.
The problem with ECT is that it's really only useful
for treatment resistant depression.
It doesn't actually target the manic aspects
of bipolar depression and bipolar disorder,
but nonetheless is used when drug treatments don't work.
Some of the negatives of electric shock therapy
or electric convulsive therapy, ECT,
is the proper acronym and way it's described,
is that it's quite invasive, right?
This is something that you need to go to the hospital for
and oftentimes there's some inpatient care required
after the electric convulsive therapy.
It's a fairly high cost, especially for those
that don't have insurance.
And of course, it requires anesthesia. For most people, that's not going to be a problem,
but for many people that could be a problem. And there's often some associated memory loss.
And so the memory loss, the invasive nature of ECT and the cost, oftentimes rule out ECT
for most patients. and that's why
it's sort of a late stage or kind of last resort type thing for treatment resistant depression.
Nowadays, ketamine type therapies done repeatedly, or other treatments, for instance, transcranial
magnetic stimulation, which is basically non-invasive.
It's a coil that's placed on the outside of the skull, excuse me.
And we can more accurately refer to it as repetitive or RTMS, repetitive transcranial
magnetic stimulation.
Transcranial magnetic stimulation is a tool that allows researchers and clinicians to reduce
the amount of activity in specific neural circuits so they can actually target the magnetic field
to particular neural circuits to reduce activity in those neural circuits.
Again, it's minimally invasive. It has been shown to be effective in both
Increasing neural plasticity in positive ways as well as reducing
Depressive episodes and in a few instances in reducing
The amplitude or the intensity of manic episodes and people with bipolar disorder. The problem is it's still a very early technique.
There aren't a lot of clinics and labs doing it.
I'm starting to see more advertisements,
literally commercial clinics that are advertising RTMS
or TMS.
I encourage you to approach those clinics with caution.
I'm of the mind that if those clinics are not either closely
or maybe you indistently associated with a research institution
that's really up on the latest of RTMS.
You'd be wise to at least do your research, right?
And explore, talk to other patients who've
done these treatments.
But certainly in university hospitals
and in clinical settings and research settings,
RTMS is being used as a way to, for instance,
reduce the activity of certain limbic circuitries,
so that people are just overall less excitable and manic, or to activate, because it can
also be used for activation now, certain neural circuits, activate, for instance, the
parietal inputs that top down control over the limbic system.
This is all happening right now.
So we have ECT, repetitive TMS, or RTMS, and then, as I mentioned earlier, ketamine therapies, most of those are targeted
toward the depressive aspects of manic depression.
So for people with bipolar disorder
that doesn't include depression,
those are gonna be less effective.
But overall, it's going to be the talk therapies
of the sort that we discussed earlier.
Where a moment ago, plus drug treatments,
almost always lithium will be explored,
plus some treatments for the
depressive episodes in particular if those depressive episodes are present.
Nowadays there's a lot of excitement about psilocybin, which is a psychedelic.
In the US, psilocybin is still illegal.
It is not legal, meaning you can get in a lot of trouble for possessing it, certainly
for selling it, et cetera.
But psilocybin is being explored as a clinical therapy in certain laboratory settings in
particular at Johns Hopkins School of Medicine.
It's being explored in human patients for the treatment of major depression for OCD, I believe,
as well.
But certainly for major depression and for eating disorders.
And it seems from the initial wave of publications from that work done by the incredible Matthew
Johnson, or Dr incredible Matthew Johnson,
or Dr. Matthew Johnson,
who was a guest on this podcast before.
He's also been on the Tim Ferris podcast.
He's been on the Lex Friedman podcast.
Dr. Matthew Johnson came on this podcast
and talked about some of the work with psilocybin
for the treatment of depression,
very impressive results there.
And as you can imagine,
very impressive results for the major depressive episodes for bipolar. However, at least to my knowledge. Again, to my
knowledge, there have not been any controlled clinical trials exploring
psilocybin for the mania associated with bipolar disorder. If someone out there is
aware of those clinical trials, please let me know. I'll do an update in a future
podcast. But right now, no knowledge from me about psilocybin clinical trials
for the manic component of bipolar disorder.
A number of people are probably also going to wonder
about whether or not cannabis or medical marijuana
is useful for bipolar disorder.
To address this, I looked to some previous lectures
and some clinicians at Stanford psychiatry.
This question was asked of them.
And as it turns out, cannabis does not seem to be effective
for the treatment of the manic phases of bipolar disorder
or for the treatment of the major depressive component.
The only treatment perhaps, or I should say,
the only situation perhaps in which it might be useful,
and this is what was relayed to me, is that it may help with sleep in certain people that
are having trouble with insomnia.
Though nowadays it's far more common for people in manic episodes to be prescribed things
like trasidone or other benzoes, benzodiazepines in order to try and get sleep within the manic
episodes and benzodiazepines and trasidone, et cetera, work largely through the so-called GABA system.
This is a neurotransmitter that causes reductions in excitability of neurons, hence why it's
being used to try and calm people down and allow them to sleep during their manic episodes.
So not a lot, or essentially no data, supporting the use of cannabis for the treatment of bipolar
disorder per se, nor data supporting the use of psilocybin for the treatment of bipolar disorder per se, nor data supporting
the use of psilocybin for the treatment of bipolar disorder per se.
But I realize as I say that, that there are going to be a number of people that may have
had positive or negative experiences with cannabis or psilocybin as they relate to bipolar
disorder.
So please, if you're willing or comfortable, put that.
If you're comfortable into the comment section on YouTube.
And of course, if you are aware of any studies
on cannabis or psilocybin showing positive outcomes
for the treatment of bipolar disorder,
please provide links or PubMed ideas to those,
I'd love to prove those studies.
There are two natural pathic, or I should say,
nutrition supplement based approaches
to bipolar disorder, they get talked
about a lot.
And one of them shows some interesting promise or effectiveness even in a limited context.
Before marching into this description of these two compounds, in fact, before even mentioning
these two compounds, I do want to emphasize what's been said and written about over and over
again and what
was relayed to me from expert psychiatrist.
It is not wise to rely purely on talk therapy or on natural approaches to the treatment of
bipolar disorder, given the intensity of the disorder and the high propensity for suicide
risk and people with bipolar disorder.
It is a chemical and neural circuit disruption
and it needs to be dealt with head on
through the appropriate chemistry
and prescription drug approaches
from a board certified psychiatrist.
I don't say this to protect me.
I say this truly to protect those who either suffer from
or think they may suffer from bipolar disorder.
If you know someone who you think might suffer from bipolar disorder. Now, all that is not to say
that there aren't useful lifestyle interventions that can support people with bipolar disorder.
So I just briefly want to mention those. And again, I'm lifting the statement I'm about to make
from some excellent online lectures from psychiatrists at Stanford and elsewhere, which essentially
say that, of course, of course, of course, getting better sleep, getting adequate exercise,
getting proper nutrition, having quality, healthy social interactions, even getting regular
sunlight in the day and avoiding bright light at night, all of those things are going to braid together to support
the nervous system and the psyche of somebody with bipolar disorder, but they braid together to
port the psyche and the neurochemistry and the neural circuits of anybody and everybody.
So they have generally a modulatory effect. That is, they are indirectly shifting the likelihood
that somebody might have an episode
or the intensity of an episode,
in particular the depressive episodes, right?
You can imagine how someone who's heading
into a depressive episode,
maybe they're on a lower amount of medication
or they haven't yet medicated
for the depressive episode of bipolar,
and now they're making sure,
or their family is making sure
that they're getting exercise sunshine,
eating correctly, social engagement, et cetera.
Of course, it makes perfect sense why they would have perhaps a shallower drop into depression
or maybe an offset of the episode.
That said, most all, if not all people with bipolar disorder are likely to need some sort
of drug therapy intervention in order to help them.
So lifestyle factors are always important and all individuals, those suffering from psychiatric conditions or not.
But in some conditions of the mind and body, those lifestyle interventions can have a greater
effect in offsetting symptoms.
Whereas in bipolar disorder, I think it's naive and in fact wrong to say that lifestyle
interventions alone are going to prevent, especially the
extreme forms of mania and depression.
Again, bipolar disorder being so serious and carrying such high suicide risk, we just have
to point this out again and again.
Now with that said, there are two substances generally found as supplements, although there
are other sources of them as well, including within nutritional sources, that have been shown,
at least in some studies, to be pretty effective in adjusting the symptoms of bipolar disorder.
And those two things are inocetal and omega-3 fatty acids.
Now, inocetal is a compound that has taken for a variety of reasons.
It's something we've talked about in the podcast before.
I personally take inocetal, not because I have bipolar disorder.
In fact, I'm quite lucky that I don't have bipolar disorder,
but I take in Nostatol at 900 milligrams of myo and Nostatol
every third night or so in order to improve my sleep.
It's something that I've added to my sleep stack.
It's something that I found greatly enhances
the depth and quality of my sleep.
And if I wake up in the middle of the night
to use the bathroom, et cetera, it's greatly enhanced my ability to fall back asleep when I want to go back to sleep.
It also seems to have a fairly potent anti-anxiety effect during the day. And as I discussed in our
episode about obsessive-compulsive disorder, inocetal has been used at high dosages. Again,
I should say, myocetal has been used at high dosages, you know, levels
of, you know, even 10, 18 grams. Those are massive dosages, by the way, to deal with certain
symptoms of OCD, to limited success. And I should mention that high dosages of 10 or 18 grams
of anocytol can cause a lot of gastric discomfort, et cetera. If you want to learn more about
anocytol, and it's various uses,
I encourage you to go to examine.com where there's this so-called human-effect matrix,
and that human-effects matrix will describe the many places in which myonocetal and other forms of
inocetal have been shown to be effective, in, for instance, reducing anxiety, enhancing sleep,
and on and on. Myonocetal is important because myo and acetal,
and we can just say in acetal,
is related to so-called second messenger pathways.
I don't wanna get too deep into second messenger pathways,
but when certain substances bind,
like neurotransmitters to a receptor on a cell surface,
oftentimes those receptors themselves will open
and allow the passage of ions
and other things into a cell.
Oftentimes they will engage what are called second messenger systems, that is they will
trigger mechanisms within the cell to then go do other things.
This is probably something we should get into in real detail in a future episode for those
of you that really want to nerd out on cell cell signaling, which is a favorite topic of
mine.
In any case, inositol is related to a number of so-called second
messenger systems, this handoff or this kind of stimulating of changes within a cell that
can inspire changes in what's called membrane fluidity, can actually make the membranes
of cells, the outside fence around a cell, which is made up of fatty stuff, it can change
the fluidity, meaning how readily
things can float around in the membrane.
We think of cells as very rigid, like there's a cell, there's a neuron or there's an immune
cell, but actually those cells have a fatty outside, and particularly neurons have a fatty
outside, it's a thin fatty outside, it's called the cell membrane, and things are floating
around in that cell membrane,
but it's kind of like gelo that hasn't quite fixed.
And so things like receptors moving into the synapse,
or moving out of the synapse for homeostatic plasticity.
Things like the ability for certain genes
to be turned on in a cell or not turned on
can depend a lot on things that are happening
in that cell membrane and how readily
things move around in the cell membrane.
One way to think about this whole picture of membrane fluidity is that just imagine that
everyone of yourselves has this layer, it's kind of a gelatinous like layer, and there
are lots of little rafts floating around in there.
But those rafts are able to move more quickly from one place to another or get more stuck in one place
or another depending on how set that jello is.
Inositol and lithium, and as we'll talk about next, omega-3 fatty acids seem to change
the fluidity of those membranes.
In other words, they allow things to move in and out of those membranes more readily or
not.
And this is no surprise given that those membranes are made out of fatty stuff.
In particular, the membranes of neurons are called a lipid bilayer.
It's two layers of fat.
Okay, bi means two, lipid fat.
And omega-3 fatty acids of the sort that are found in certain fish and that
fatty fish in particular and that are found in fish oil, cod liver oil, etc. Omega-3
fatty acids, when we ingest them, are used for a lot of different things, but they can
be readily incorporated into pathways or directly incorporated into cell membranes, changing
the way those cell membranes work, and if those cell membranes are the cell membranes of
neurons, changing the way that neurons work.
So the ability for fish oil, and in particular, the omega-3 fatty acids, which come in varieties
like EPA and DHA, we'll talk about that in a moment, have been explored at relatively high dosages for their
ability to offset some of the effects of mania and to offset the effects of depressive episodes
in bipolar disorder.
And actually the data there are pretty impressive, although they are varied.
Meaning you will find several studies, and I'll mention a few, that found no effect of omega-3
supplementation through fish oil. Usually it's capsuleed fish oil, although fish oil can also be
taken, excuse me, in liquid form. Oftentimes taking in liquid form is the more cost-efficient
way to do it. Taking in capsule form is the more palatable way to do it, because fish oil for a
lot of you doesn't taste good. But nonetheless, there are several studies that have shown that supplementing
with fish oil or omega-3 fatty acids at levels of, for instance, four grams per day for
a period of time.
This is a study that we will link in the show notes.
This is Murphy at all, 2012.
This is a fatty acid supplementation of 70% EPA to DHA.
Actually worse in symptoms of mania over a period of about 16 weeks,
which on the face of it makes it seem like, okay, omega-3 fatty acid supplementation very
likely to not be good for bipolar disorder.
And yet, that was the manic phase.
When one looks at some of the other studies of omega-3 fatty acid supplementation, there
is, for instance, a study published in 1999. This is a
much higher dosage supplementation with omega-3 fatty acid. This is a 9.6 grams of fish oil per day
for four months. And that actually greatly reduced symptoms of bipolar depression compared to the
control group, which received olive oil. Olive oil is a different form of fat, monon, saturated fat,
but doesn't contain as much of the omega-3 fatty acids and so forth.
So 9.6 grams of fish oil per day over four months is a lot of fish oil,
to be ingesting on a given day.
This was a double-blind study.
This was only carried out, I should mention, in 30 subjects,
but it was males
and females, and the age range was pretty broad.
Anywhere from 18, all the way up to 64 years of age, which is important given the sort
of large and two-tonal or changes over time that one sees in bipolar disorder.
Here's the major takeaway.
Sumplementing with high dose omega-3s does seem to be beneficial for a good number of
people with bipolar disorder.
However, again, I want to highlight, however, it should not be viewed as the only treatment
approach for bipolar disorder.
This goes back to what I was saying before about the essential need in most every case
for high potency prescription drug treatments prescribed by-board certified psychiatrists
for bipolar disorder. However, omega-3 supplementation
does seem to improve or reduce the depressive symptoms in the major depressive episodes of bipolar.
And there are a couple studies and we'll link to these in the show notes as well that show that it
may even improve some of the manic episodes as well, meaning it reduces some of the manic symptoms.
Now, I say all this from a place of great caution because I know, especially for listeners
of this podcast, there's a lot of interest in the behavioral tools, the supplement-based
tools, the nutrition tools that can support bipolar disorder.
But I don't think I can overemphasize enough that, especially for bipolar disorder and
the great risk of suicide and suffering and inappropriate spending, or I should say maladaptive
spending and impulsivity
that's associated with bipolar disorder, that it's hard to imagine a scenario in which just
talk therapy and fish oil and lifestyle interventions are going to completely suppress or treat
bipolar disorder. People with bipolar disorder really need to consider the full picture of treatments,
the drug treatments, the talk therapy treatments, and lifestyle treatments, and
nutraceutical, or we can say supplement-based treatments such as omega-3 supplementation,
as a full and necessary picture for dealing with their illness.
I'd be remiss, however, if I didn't emphasize that the omega-3 fatty acid supplementation
is very interesting, not just in terms of the subjective effects,
you know, people saying they feel less depressed or able to sleep better or maybe in some reduction
in manic symptoms. There's actually been some really good brain imaging to try and understand how
omega-3 fatty acid treatments are actually changing the brains and neural circuits of people with bipolar,
and I will put a reference to this. This is a paper that was published in the American Journal of Psychiatry.
It's entitled Omega-3 fatty acid treatment
and T2 whole brain relaxation times in bipolar disorder.
I don't have the opportunity to go into a lot of detail right now
about what T2 whole brain relaxation times are.
But basically when people go into a MRI or F functional MRI
scanner, magneticant imaging scanner.
What they're getting essentially is a pulses of magnetic fields and the way that brain structures
and neural activity can be evaluated has a lot to do with the sort of spinning or not
sort of has to do with the spinning and the relaxation times of different, different elements.
Literally, the protons and electrons within the neuron, so it gets really detailed there.
And the relaxation time is essentially looking at how quickly some of that spinning returns
to rest.
And in particular, the fact that the relaxation times are different for aqueous, that is liquid versus
lipid, fatty versus other components of brain tissue. And basically what this study shows
is that the membranes of neurons within the brains of these people with bipolar disorder
showed more fluidity, more ability of things to move in and around the membranes,
which we know is an important component of neural plasticity.
In bipolar subjects that were treated with omega-3 fatty acids as compared to bipolar subjects
that did not receive omega-3 fatty acids.
And fortunately, this study also include a healthy comparison group where they could
essentially find that people with bipolar disorder who supplemented with omega-3s had changes
at the cellular level and the neural circuit level that brought their brains and neural circuits
closer to that of the healthy comparison subjects.
So while I don't want to point to omega-3 fatty acid supplementation as the be all end
all of treatment for bipolar disorder, certainly it is not. It does have a strong mechanistic basis for its possible
support of neural circuitry, of neural plasticity, and in particular the ability to make changes
in cell membranes that are very reminiscent of some of the neural circuit changes and
changes in membrane fluidity that are seen with lithium treatment and other known prescription
drug treatments that have been established now for decades to be very effective for
bipolar disorder. So what that says is that omega-3 supplementation while not
the only intervention that one should consider is something to consider and
talk about with your doctor and it's operating in powerful ways. It's not just
that it's changing, for
instance, your gut microbiome, which is powerful, but is indirect to the brain. It
does seem to be having direct effects on neurons and neural circuits. Before we
begin to conclude our discussion about bipolar disorder, I want to talk a
little bit about this word disorder. And this is a theme that doesn't just relate
to bipolar disorder, but other psychiatric disorders as well. And when we think of a disorder,
we think of something that is really detrimental to us,
something that really impairs our ability to function
and work in school and relationships
and really starts to pull down our health status
in a variety of ways.
And certainly bipolar disorder meets those criteria.
However, there is this idea that things like bipolar disorder,
even things like schizophrenia, in some cases, are responsible for some of the creative aspects
or the creative works that have been observed and carried out by human beings for many centuries.
And believe it or not, there are good data to support the fact that certain aspects of mania are associated with creativity.
Now, we are long overdue for an episode about creativity,
it's neural circuit basis, it's chemical basis,
here on the Huberman lab podcast,
and certainly we will have that conversation.
But in the meantime, I'd like to just briefly touch upon
this idea that certain occupations are associated
with a higher incidence of bipolar depression.
And in fact, it's been explored at a research level.
Really, there are data pointed to the fact that certain individuals of certain occupations
tend to be more creative, and that creativity is associated with.
Again, associate, this isn't causal, it's associated or correlated with higher levels
or incidents of bipolar depression and maybe
even other forms of depression.
So this is a study looking at mood disorders in eminent individuals.
So these are people that are not just good at what they do, but are exceptional at what
they do and explored the percentage of people in given professions with either depression or mania.
And this was actually a data set gleaned from more than 1,020th century Westerners based
on their biographies that were reviewed by other people.
So it's a bit of an indirect measurement.
This isn't psychiatrist data.
This is data, or I should say these are data data that were compiled from self-reports or from reads of self-reports
And they explored a number of different professions
So for instance they looked at people in the military or people who were professional athletes or natural scientists or social scientists
People who occupied positions in public office or were musical performers of artists, nonfiction writers, poetry, etc.
There are a lot of professions here. I will post this or I'll post a link to it in the show
note captions for you to prove, but I'll just give you a sense of the extremes on this graph
because they're very interesting. Turns out that if you were to look at the profession,
or I should say, among the professions they looked at in this study, because they didn't look at all professions, those in the military and those who are professional athletes or
had jobs in the social or natural sciences had the of those, there was a lower percentage
of those that had depression or mania.
In some cases, like those who are professional athletes didn't seem to have, there was
no incidence of mania, at least in this data set.
Whereas at the opposite extreme of the graph, those that were poets, so these are imminent
individuals, people that were exceptional poets, exceptional fiction writers, exceptional
artists or nonfiction writers.
Well, they're especially for the poets, you find that as many as 90% of these very successful poets had either depression
or mania. As high as 90%. That's incredible. Contrast that with military where it's as few as
10% or professional athletes, where it's as few as 20% and for the professional athletes,
as I mentioned before, none of them had mania. So does this mean that being a poet will make you manic or depressed?
Well, first of all, let's look at the poetry category.
It turns out that 75% of these eminent poets, these highly accomplished poets, had major
depression.
Whereas only about 20% of those poets had manic episodes.
Okay.
So again, it's not that being a poet is going to give you Mania.
Certainly we're not saying that.
It's not that being a poet is going to give you depression, but it turns out that people
with depression and people with depression and Mania seem to gravitate towards poetry
or at least are very successful at poetry.
Again, associative, correlative, no causal relationship here.
But it is really striking to see how the creative occupations, poetry, fiction, art, nonfiction writing, even though nonfiction writing is about nonfiction, it's still creative,
music composition, theater, much higher incidence of things like Mania.
And in fact, for the people in theater, the actors, even though the overall occurrence
of depression in Mania is lower than that in poets, the fraction of those individuals that
have Mania is exceedingly high.
It's about 30% of those that they looked at who are actors have many,
manic episodes or have full-blown mania.
So I'm referring to these data because, first of all, I find them incredibly
interesting. Right up until now, we've been talking about bipolar disorder and
other mood disorders for their maladaptive effects. And again, they're
extremely maladaptive, much, much higher, instance of suicide, etc. But we'd be
wrong to say that certain aspects of manic episodes
don't lend themselves well to creativity,
or that certain aspects of major depression
don't lend themselves well to creativity
or to the performing arts or to poetry.
That said, in no way, shape, or form,
do I believe that being depressed is a good thing,
or that being manic is a good thing.
Again, we return to the basic foundational criteria for bipolar disorder and major
depression, which is that the pressured speech, the not sleeping, the incredible increases
in energy and the flights of ideas are generally not going to lead or I think it's fair to
say are not going to lead to good places.
In fact, often lead to bad places.
But we would also be wrong if we didn't consider the fact that there is a somewhat inextricable
relationship between mania and creativity.
And it could be that hypomania or brief periods of mania, maybe even an hour a day or 30 minutes
a day of composing or
writing poetry, maybe even some of the lows that we feel, some of the sadness, some of the grief,
some of the nostalgia that we feel provided that it's not pathologic, that it's not persistent
for the four or seven days that are diagnostic of bipolar two and bipolar one disorder respectively.
Well, then we can start to view emotional states
as something that can actually lend themselves
to positive outcomes and maybe even to creativity
and to improve docuations.
So it's important that we have a nuanced view
of what sadness versus depression versus major depression are.
It's important that we distinguish between being erratic,
being very energized and and full-blown
bipolar disorder.
And I raise this for another reason as well.
Nowadays it's very common to hear people saying, oh, you know, that person is OCD.
Well, on the episode about OCD that I did a few weeks back, that you can find if you like
it, HubermanLab.com.
In that episode, I pointed out that OCD obsessiveive Compulsive Disorder is very maladaptive, right?
I think it's number seven, as I recall, on the list of debilitating diseases, all diseases
in terms of lost time at work, suffering relationships, et cetera.
So it's a really serious condition.
And yet we often hear, oh, that person is obsessive.
And as I pointed out, there is obsessive compulsive personality disorder.
And then there is obsessive compulsive tendencies, which actually benefit people.
But that is distinct from obsessive compulsive disorder as a clinically diagnosed thing.
Similarly, we hear that, oh, somebody's being bipolar or, you know, they're all over the
place, they're bipolar.
Well, that's a very subjective and kind of label that people give one another in passing.
More and more often I'm hearing this.
And yet bipolar disorder, whether or not it's BP1 or BP2, are extremely maladaptive
and extremely associated with high suicide risk.
So while I'm not here to police people,
I'm not certainly not the word police
or the nomenclature police,
I do think that whether or not you refer to people as OCD
or as bipolar, it's better, that's up to you.
It's not my place to say,
but I do think it's important that all of us understand
that these psychiatric conditions carry with them
tremendous maladaptive weight.
So today we've really done a deep dive into bipolar disorder and to both the
manic and the depressive components that are present or can be present in bipolar disorder and
the different forms of bipolar disorder and some of the major treatments for bipolar disorder in
particular lithium and it's underlying mechanisms and some of the neural circuit and chemical
basis and neural plasticity basis of the treatments for bipolar disorder
in particular, homeostatic scaling or homeostatic plasticity.
All of that, of course, is relevant to bipolar disorder
and I hope will be useful in your understanding
and maybe even in your pursuit of treatments
for bipolar depression, bipolar disorder for you
or other people.
I also hope that it will be useful in your understanding
of how brain circuits work in normal conditions or in conditions where there is no disease
state or maladaptive conditions. Homesthetic plasticity is present in all of us.
Membrane fluidity due to how easily things move around in the surface, the fatty layers on
the outside of neurons and the movement of receptors in and out of neurons, that is present in all of us.
The influence of omega-3 fatty acids
is central to that discussion.
As is the discussion about various drug treatments,
because even if you're not somebody who's taking
a drug treatment or who is pursuing a drug treatment
for bipolar disorder or another psychiatric condition,
your serotonin levels, your dopamine levels,
your acetacoling levels, all of these play into
what we call your mental and physical health.
In fact, if any of you are interested in the various categories of neuromodulators and
tools to adjust those neuromodulators under more standard, non-disease conditions, we did
an episode on neurochemicals and how to control them.
You can find that at hubermanlab.com, along with all other episodes of the huberman lab
podcast.
You should mention everything as timestamped, so you can navigate to the specific topics and
tools of interest to you.
And meanwhile, I just want to thank all of you for joining me on this voyage through
the biology and the treatments for bipolar disorder.
I do hope you found it beneficial, both for yourself and for others.
I just want to remind people that bipolar disorder is an extremely serious condition. If you suspect that you have bipolar disorder or you know somebody who does, please
make sure that you or they talk to a qualified health professional. If you're learning
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