Huberman Lab - Erasing Fears & Traumas Based on the Modern Neuroscience of Fear
Episode Date: December 6, 2021In this episode, I discuss fear and trauma, including the neural circuits involved in the "threat reflex" and how specific experiences and memories come to activate that system. I also discuss how our... body is involved in trauma and fear. First, I describe the logic of fear mechanisms and how "top-down" processing-- meaning connections from the parts of the brain that assign meaning to our feelings, are involved in fear and erasing fears and traumas. Then I discuss what successful fear and trauma treatment must include and consider various treatments for whether they meet that standard, such as EMDR, Cognitive Behavioral Therapy, Ketamine, other drug-assisted therapies, and more. I also review new data on how 5 minutes per day of deliberate, self-imposed stress can erase fear and depression. And I review the role that social connection plays in erasing or maintaining fears by activating specific molecular pathways in the brain and body. Finally, I review supplementation with over-the-counter compounds for their effects on anxiety and fear and when to take them, if at all. 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) Introducing Fear, Trauma & Trauma (00:02:31) Sponsors: AG1, LMNT (00:06:49) What is Fear? (00:11:45) Autonomic Arousal: “Alertness” vs. “Calmness” (00:13:44) Hypothalamic-Pituitary-Adrenal Axis (HPA axis) (00:17:36) “The Threat Reflex”: Neural Circuits for Fear (00:28:24) Controlling Fear: Top-Down Processing (00:32:27) Narratives: “Protective or Dangerous” (00:35:58) Attaching Fear to Events: Classical Conditioning & Memory (00:41:45) How Fear Learning Occurs: Long Term Potentiation, NMDA (00:46:10) Extinguishing (Reducing) Fears (00:50:25) Cognitive (Narrative) Therapies for Fear (00:57:56) Repetition of Narrative, Overwriting Bad Experiences with Good (01:05:28) EMDR: Eye Movement Desensitization Reprocessing (01:14:00) Social Connection & Isolation Are Chemically Powerful (01:18:23) Trans-Generational Trauma (01:25:00) PTSD Treatments: Ketamine, MDMA, oxytocin (01:39:25) How Do You Know If You Are Traumatized? (01:46:16) Deliberate Brief Stress Can Erase Fears & Trauma (01:49:50) Erasing Fears & Traumas In 5 Minutes Per Day (01:59:42) Nutrition, Sleep, & Other General Support Erasing Fear & Trauma (02:02:30) Supplements for Anxiety, Fear: Saffron, Inositol, Kava (02:10:00) Synthesis (02:11:46) Zero-Cost Support, Sponsors, Supplements, Instagram, Twitter Title Card Photo Credit: Mike Blabac Disclaimer
Transcript
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Welcome to the Huberman Lab podcast where we discuss science and science-based tools for everyday life.
I'm Andrew Huberman and I'm a professor of neurobiology and
Ophthalmology at Stanford School of Medicine. Today, we're going to talk about the neuroscience of fear.
We are also going to talk about trauma and post-traumatic stress disorders.
The neuroscience of fear has a long history in biology and in the field of psychology.
However, I think it's fair to say that in the last ten years, the field of neuroscience has shed light on not just the neural circuits,
meaning the areas of the brain that control the fear response and the ways that it does it. But some important ways to extinguish fears using behavioral therapies, drug therapies, and
what we call brain machine interfaces.
Today we are going to talk about all of those, and you are going to come away with both
an understanding of the biology of fear and trauma, as well as many practical tools to
confront fear and trauma. In fact, we are going to discuss one very recently published study in which five minutes
a day of deliberate exposure to stress was shown to alleviate longstanding, depressive,
and fear-related symptoms.
We will get into the details of that study and the protocol that emerges from that study
a little later in the podcast.
But it stands as a really important somewhat counterintuitive example of how stress itself
can be used to combat fear.
To give you a sense of where we are going, I'll just lay out the framework for today's
podcast.
First, I'm going to teach you about the biology of fear and trauma.
Literally the cells and circuits and connections in the body and chemicals in the body that give rise to the so-called fear response. And why
sometimes but not always fear can turn into trauma. I will also describe the
biology of how fear is unlearned or what we call extinguished. And there too
you're going to get some serious surprises. You're going to learn for instance
that we can't just eliminate fears.
We actually have to replace fears with a new positive event.
And again, there are tools with which to do that.
And I will teach you those tools today.
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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So what is fear? Well, fear falls into a category of nervous system phenomenon
that we can reliably call an emotion.
And it is hotly debated nowadays.
And it's been hotly debated really for centuries.
What an emotion is and what an emotion isn't.
Now, that's not a debate that I wanna get into today.
I think it's fair to say that emotions include responses
within our body, quickening of heart rate,
changes in blood flow, things that we experience
as a warming or a cooling of our skin,
but that there's also a cognitive component.
There are thoughts, there are memories.
There's all sorts of stuff that goes on in our mind
and in our body that together
we call an emotion. And there's a vast amount of interest and literature devoted to trying
to understand how many different emotions there are, how different people experience emotions.
And that's certainly a topic that we will embrace in a future podcast episode. But today
I just want to talk about fear as a response. Because when we talk about fear
as a physiological response and as a cognitive response, then we can get down to some very
concrete mechanisms and some very concrete and practical tools that can be used to deal with fear
when fear is not wanted. So let's talk first about what fear isn't. Most people are familiar with
stress, both as a concept and as an experience. Stress is a physiological response. It involves
quickening of the heart rate, typically quickening of breathing, blood flow getting shuttled to
certain areas of the brain and body and not to others. It can create a hyper vigilance or an awareness.
Typically that awareness is narrower, literally narrower in space like a soda straw view of
the world than when we are relaxed.
And it is fair to say that we cannot have fear without having several, if not all of the
elements of the stress response.
However, we can have stress without having fear.
Likewise, people are familiar with the phrase,
or the word, rather, anxiety.
Anxiety tends to be stress about some future event,
although it can mean other things as well.
We can't really have fear without seeing or observing
or experiencing some of the elements
of anxiety, but we can have anxiety without having fear.
So what you're trying to realize is that fear is built up from certain basic elements
that include stress and anxiety.
And then there is trauma.
And trauma also requires a specific what we will call operational definition.
An operational definition is just a definition that allows us to have a conversation because
we both agree on or mostly agree on what the meaning of a given word is. It makes conversations
much easier. In fact, I would argue if we all had operational definitions for more things
in the world that there would be fewer misunderstandings and arguments and we'd all move a lot further as a species.
But that's another topic entirely.
The operational definition of trauma is that some fear took place, which of course includes
stress and anxiety, and that fear somehow gets embedded or activated in our nervous system
such that it shows up at times when
it's maladaptive, meaning that fear doesn't serve us well and it gets reactivated at
various times.
Like, when you first wake up in the morning, if you're not in the presence of something
that scared you, but you suddenly have what feels like a panic attack and you're in deep
fear, well, that's post-traumatic stress.
That's post-traumatic fear.
So I don't want to get bogged down too much in the nomenclature, but what I'm doing here
is building up a sort of series of layers where stress and anxiety form the foundation of
what we're calling fear and trauma.
And then there are other phrases out there that we would be remiss if we didn't mention
things like phobias and panic attacks.
Panic attacks are the experience of extreme fear, but without any fear-inducing stimulus.
So it's kind of like trauma.
And a phobia tends to be extreme fear of something specific, fear of spiders, fear of heights,
fear of flying, fear of dying, these kinds of things.
The reason for laying all that out there is not to create a word soup to confuse us.
Rather, it is to simplify the issue because now that we acknowledge that there are many
different phrases to describe this thing that we call fear and in related phenomena, we
can start to just focus on two of these issues, fear and trauma, as it relates to specific
biological processes, specific cognitive processes,
and we can start to dissect how fears are formed, how fears are unformed, and how new memories
can come to replace previously fearful experiences.
So in this effort to establish a common language around fear and trauma, I want to point out
autonomic arousal. Autonomic arousal relates
to this aspect of our nervous system that we call the autonomic nervous system. Autonomic
means automatic. That's somewhat of a misnomer because there are aspects of your autonomic
nervous system that you can control. But your autonomic nervous system controls things
like digestion, urination, sexual behavior, stress,
when you want to be awake, when you want to be asleep,
it basically has two branches to it,
two branches meaning two different systems.
One is the so-called sympathetic,
autonomic nervous system has nothing to do with sympathy,
has everything to do with increasing alertness.
Think of the sympathetic nervous system
as the alertness nervous system.
It's what ramps up your levels of alertness.
Ramps up your levels of vigilance.
Think about it as the accelerator on your alertness and attention.
The other branch of the autonomic nervous system is the so-called parasympathetic branch of the autonomic nervous system.
I know that's a mouthful.
The parasympathetic branch of the autonomic nervous system are the cells and neurons
and chemicals and other aspects of your brain and body that are involved in the calming
nervous system.
So sympathetic is alerting, parasympathetic is calming, and it acts as sort of a seesaw
to adjust your overall level of alertness.
So for instance, right now, I'm alert, but I feel pretty calm.
I'm not ready to go to sleep or anything like that.
I don't feel like I need an app. I'm alert, but I'm calm. I'm not in a state of stress or panic.
So that seesaw. We could imagine is more or less level. Maybe it's tilted up a little bit to the
side of increased sympathetic or alertness rather than parasympathetic because I feel wide awake.
If I were sleepy, the opposite would be true. The parasympathetic side would be increased
relative to the sympathetic side.
There are many different aspects
to the autonomic nervous system,
but one of the main aspects is an aspect
that's going to come up again and again and again today.
It's very important that you understand what it is.
It's called the HPA axis.
The HPA axis stands for hypothelamic pituitary adrenal axis.
The hypothalamus is a collection of neurons.
It's an area of your brain real estate that's deep in the brain at the base of the brain
that contains many, many different areas that control things like temperature and desire
to have sex, desire to eat thirst.
It also controls the desire to not mate have sex, not eat, not drink more water,
or any other type of fluid.
So it has accelerators and breaks in there as well.
The hypothalamus connects to the so-called pituitary.
The pituitary lives close to the roof of your mouth.
It releases hormones into your bloodstream.
And so the hypothalamus has this ability to trigger the release or prevent
the release of particular hormones like cortisol, or the hormones that go stimulate ovaries to produce
estrogen, or testes to produce testosterone, or adrenals to produce adrenaline. And speaking of
the adrenals, that A and the HPA are the adrenals. You have two glands
that sit above your kidneys and you're lower back. They receive signals by way of nerve cells,
neurons and by way of hormones and other things released from the brain and elsewhere in the body.
And they release different hormones and other types of chemicals into the body. And the two main ones
that you need to know about today are adrenaline, also called epinephrine, and cortisol.
Both of those are so-called stress hormones,
but they're not always involved in stress.
They're also involved in waking up in the morning
when you arise from sleep.
And so this HPA axis should be thought of
in the following way.
The HPA axis includes a piece of the brain,
the hypothalamus, the pituitary, and the adrenal. So it's a beautiful three-part system that can
use your brain to alert or wake up your body and prepare it for action. And it can do that in the
short term by triggering the release of hormones and chemicals that make you alert and ready to go right away
and by triggering the release of neurotransmitters and hormones and other chemicals that give that alertness a very long tail,
a very long latency before it shuts off. And that's important because one of the hallmarks of fear and one of the hallmarks of trauma is that they involve fear responses that are
long lasting. Even if those fear full events, the events in the world that trigger the
HPA access can be very brief, like a car that almost hits you as you step off the curb,
or something gunshot that goes off suddenly, and it's just a very quick like, you know,
500 millisecond or one second event, the fear response can reverberate through your system because the chemicals that are
involved in this HPA axis have a fast component and a longer lasting component.
And the longer lasting component can actually change, not just the connections of different
areas of the brain and the way that our organs work,
like our heart and the way that we breathe, it actually can feed back to the brain and literally
control gene expression, which can take many days and build out new circuits and new chemicals
that can embed fear in our brain and body. And that might sound very depressing, but there's a
reason and there's an adaptive reason why there's the slow and fast phase of the HPA axis and the fear response. And fortunately,
that gene expression and the long arc of the fear response, the way it kind of lives in
our system, kind of like a phantom in some ways, can also be leveraged to undo the fear response, to extinguish the fear response and replace it
with non-fearful associations. So let's dig a little deeper into the neural circuits and biology
of fear because in doing that we can start to reveal the logic of how to attack fear if that's the
goal. We can't really have a discussion about fear without discussing the famous amygdala.
Famous because I think most people by now have heard of the amygdala. Amygdala means
almond. It's an almond-shaped structure on both sides of the brain. So you have one on the
right side of your brain and one on the left side of your brain. The amygdala is part
of what we can call the threat reflex. And this is very important to conceptualize fear as
including a reflex. So much as you have reflexes that cause you to lift your foot up if you are
to step on something sharp, you literally have a reflex within your spinal cord that causes you to
lift up one foot and extend the other one toward the ground. Believe it or not, it's a,
that you always think you step on something sharp, you pull your foot up, but you actually step on something sharp,
you pull your foot up and in pulling it up,
there's another reflex that's activated
that as you extend your other leg
so that you don't fall over.
Similarly, in the process of experiencing fear,
you have a reflex for particular events in your brain and body,
and that reflex involves things like
quickening
of your heart rate, hyper vigilance,
your attentional systems pop on, increased ability
to access, energy stores for movement and thought
and so forth.
But just like that, step on the tack reflex example.
All of the neural circuits that are associated with being calm,
with being able to go being calm, with being able
to go to sleep, with being able to visualize the full picture of your environment, literally,
to see your entire environment, or to hear other things around you, all of those get shut
down when the so-called threat reflex gets activated.
And the amygdala is part of the threat reflex so much so that we can really say that it's
the final common pathway through of the threat reflex so much so that we can really say that it's the final
common pathway through which the threat reflex flows.
In other words, the MiGdala is essential for the threat response.
But the threat reflex and the threat response is kind of a dumb response.
It's not a sophisticated thing.
It's very generic.
This is also a very important point.
One of the beauties of the fear system is that it's very generic. And this is also a very important point. One of the beauties of the
fear system is that it's very generalizable. It's not designed for you to be afraid of any one thing.
Sure, there are some debates and probably some good data out there that support the fact that
human babies are innately, meaning it requires no learning, innately afraid of certain things, like heights or snakes or spiders.
There's debate about this and that depends on,
you know, the quality of the experiment, et cetera.
But the real capacity of the fear system
is that we can become afraid of anything,
provided that this threat system is activated
in conjunction with some external experience.
So the way I'd like you to think about the amygdala
is not as a fear center,
but that it's a critical component of the threat reflex.
I'd like you to also internalize the idea
that the threat reflex involves
this activation of certain systems
and suppression of all the systems for calming
the parasympathetic system.
And now I'm going to describe the way
that information flows into and through
this threat reflex. And in doing that, it will reveal how specific things like a spider,
like a snake, like a physical trauma, like a car accident, like a fear of public speaking,
whatever happens to scare you or scare somebody, how that gets attached to this reflex because this reflex is very generic.
It doesn't really know what to be afraid of.
It only knows how to create the sensation, this internal landscape that we think of as
fear.
So while the amygdala might look like an almond, it's actually part of a much bigger complex
or collection of neurons called the amygdaloid complex.
That complex has anywhere from 12 to 14 areas depending on which neuron atomist is naming
things and carving it up in neuroscience and in much biology.
We like to joke that there are lumpers and there are splitters.
So some people like to draw boundaries between every little distinct difference and say,
oh, that's a separate area.
And other people are lumpers. And they say, well, listen, you know, why complicate things?
Let's lump those together.
I'm neither a lumper nor a splitter.
I'm somewhere in between.
I think the number 12 is a good number in terms of the number of different areas of the
amygdala.
Why is that important to us?
Well, it turns out that the amygdala is not just an area for threat.
It's an area for generating threat
reflexes that integrates lots of different types of information.
So for those of you that want to know, I'm going to give you some name, some nomenclature,
for those of you that don't, you can tune out for this, but basically information from
our memory systems like the hippocampus and from our sensory systems, our eyes, our
ears, our nose, our mouth, etc.
So taste information, vision, auditory information, touch, etc.
Flow into the so-called lateral portion of the amygdala.
Flows into, or the amygdala complex.
It flows into the lateral portion and then there are multiple outputs from the amygdala.
And this is where things get particularly interesting because the outputs of the amygdala
have a lot of different areas, but there are two main pathways. One involves
the hypothalamus, which you heard about before, this collection of neurons that control a lot of
our primitive drives for sex, for food, for thirst, and for warmth, et cetera. And it also feeds out
to our adrenals, those glands that you learned about a few minutes ago, to create a sense of alertness and action.
It also feeds out what I mean by feeds out, by the way, is there are neurons that send
wires, we call those wires, axons, connections where they can release chemicals and trigger
the activation of different brain areas.
So it feeds out to other brain areas such as the P-A-G.
P-A-G is very interesting for our discussion today.
It's the peri-aquaductal gray.
The peri-aquaductal gray contains neurons
that can trigger freezing.
Can trigger the, some people talk about the fawning response,
which is kind of an appeasing response to traumatic events,
but some people outright freeze in response to fear.
We've heard of fight or flight, and indeed the pathway that I'm describing can create
a sense of fight and cause people to want to lean in in an aggressive way to combat things
that they're afraid of, or flight to run away, essentially to avoid by mobilizing the
thing that they feel they're threatened by.
Now, even in the absence of some threat, some of the, that has, say, fear of public speaking,
might hesitate or move away from a podium
or hesitate or move away from raising their hand,
if raising their hand meant that they might be called on
and would be public speaking.
So there's fight and flight,
but there's also the freeze response.
And the freeze response, that's controlled by a number
of brain centers, but the peri-aquaductal grade, the P.A.G. is central for the freeze response. And the freeze response is controlled by a number of brain centers, but the peri-aquaductal
grade, the P.A.G. is central for the freeze response.
And neurons there also create what are called endogenous opioids.
Many of you have heard of the opioid crisis, which is a crisis of prescription medication
given out too broadly for people that don't need it who are become addicted to opioids.
Those are exogenous opioids.
But endogenous opioids are chemicals released from neurons in the P.A.G. and from elsewhere
in the body that give us a sense of numbing.
They actually numb us against pain.
And you can imagine why biology would be organized this way.
A threat occurs or something that we perceive as a threat.
We're afraid of it.
And a natural analgesic is released into our body because there's likely to be an interaction that's
very uncomfortable, that's physically uncomfortable.
So it's like we have our own endogenous release of these opioids, and that's occurring in the
P.A.G.
The other area, and again, sorry, to litter the conversation with these names of structures,
but some people seem to enjoy knowing these structures. You're fine if you just understand what the structures do.
If you want to know the names, that's fine.
But the other structure is the locus seruleus.
The locus seruleus creates a sense of arousal by releasing adrenaline, epinephrine,
and nor epinephrine related chemical into the brain.
So basically, the activation of the amygdaloid complex could be from any number of different things,
a memory of different things,
a memory of something fearful,
an actual sensory experience of something that's fearful.
And then the fear response itself is taking part
because of the threat reflex gets activated.
And that's threat reflex then sends a whole set
of other functions into action freezing,
activation of the adrenals, activation
of locus ceruleus for arousal and alertness, activation of this endogenous pain system
or anti-pain system in the P.A.G. That's one pathway out of the amygdala. The other pathway
out of the amygdala is to a very interesting area that typically is associated with reward
and even addiction. So this might come as a
surprise to many of you. In fact, it came as a surprise to me. I remember when these data were
published, but the the amygdala complex actually projects to areas of the dopamine system, the so-called
nucleus acumbens, the mesolimic reward pathway for those of you that want to look that up or
that remember from the dopamine episodes. We have pathways in our brain that are associated
with pursuit motivation and reward,
and the neuromodulator dopamine is largely responsible
for that feeling of craving, pursuit, and reward.
And this threat center is actually able to communicate with
and activate the dopamine system.
And later you will realize why that is very important
and why you can leverage the dopamine system
in order to wire in new
memories to replace fearful ones.
So I've been hitting you with a lot of names of things, but for the moment, even if you're
interested in all the neuroscience names and structures and so forth, I'd like you to
just conceptualize that you have a circuit in your brain, meaning a set of cells and connections
that are arranged in the following way.
You have a threat reflex that can be activated at any time, very easily.
But what activates that threat reflex can depend on two things.
One are prior memories, coming from brain areas that are involved in storage of memories,
or it can be immediate experiences.
Things are happening in the now.
Okay, so we're something fearful to happen.
Right now, your threat reflex could be activated.
We're you to remember something very scary that happened to you in the past, your threat
reflex could be activated.
And that threat reflex circuit has two major outputs.
One of the major outputs is to areas that are involved in the threat response, freezing,
pain management and alertness.
And the other major output is to areas involved in reward, motivation, and reinforcement.
There's a fourth component, and I promise this is the last component that we need to put
into this picture of the neural circuits for fear.
This is a circuit that involves
an area of the brain called the prefrontal cortex and some of its subdivisions, so literally
in the front. And it's involved in what we call top down processing. Top down processing
is the way that your prefrontal cortex and other areas of the brain can control or suppress a reflex.
A good example of this would be the step-on-the-tack example that I gave before.
When you step-on-attack, you immediately pull up your foot and you extend the other leg.
That's the reflex that prevents you from injuring yourself and from falling over.
However, if you wanted, not that you would want to, but
if you wanted, you could, for instance, place your foot onto attack and decide not to pull
your foot away. It would be difficult, and again, I don't recommend that you do that, but
you could override that reflex. Okay. There are other examples of reflexes like, for instance,
getting into cold water, most people will start to, you know, huddle
their body.
Most people won't want to get into the cold water.
Many people will jump out.
But all of that is reflexive.
And should you want to, you could override that reflex through top down processing.
You could tell yourself, oh, I heard on a previous Uberman lab podcast or on an Instagram
post that cold water exposure can be beneficial for metabolism
and resilience, et cetera, and indeed it can.
And you can decide to get into the water and to stretch out
your body, not to huddle, and you can fight those reflexes.
Okay.
The fighting of reflex is carried out through top-down processing,
largely through the prefrontal cortex.
You provide a narrative. You tell yourself, I want to do this, or I should do this. carried out through top down processing, largely through the prefrontal cortex, you provide
a narrative.
You tell yourself, I want to do this or I should do this, or even though I don't want
to, I'm going to do it anyway.
So top down processing is not just for getting into cold water, and it certainly isn't for
overriding reflexes that can damage us like stepping on the attack example.
It is the way in which we can override any number
of internal reflexes, including the threat reflex.
And the way that we do that is by giving a new story or a new narrative to this experience
that we call threat.
And you know the threat response, the threat response is quickening or the heart rate,
quickening or the breathing.
We don't generally like the feeling of adrenaline in our system.
Some people are so called adrenaline junkies and they get a mixture of dopamine and adrenaline
from certain high intensity events.
I confess in a, you know, in previous aspects of my life, I've tended to like adrenaline.
I don't think I was, you know, at the extreme of thrill seeking.
But I'm somebody that, for instance, I tend to like roller coasters, I've done, you know,
various things where I'm familiar with and I enjoy the sensation of adrenaline in my
body.
But I enjoy it because of the alertness that it brings and the hyperacuity that it brings.
Many people don't feel that way.
In fact, most people don't like the sensation of a lot of adrenaline in their system.
It makes them feel very uncomfortable and out of control.
We will do an entire episode about adrenaline and adrenaline junkies and adrenaline reversives
in the future, but the threat reflex inevitably involves the release of adrenaline into the
system.
And then it becomes a question of whether or not you remain still, move forward or retreat
from that adrenaline experience.
And when I say the adrenaline experience, I mean the threat reflex.
So this fourth component of fear is really our ability to attach narrative, to attach
meaning and to attach purpose to what is by all accounts and purposes, a generic response.
There's no negotiating what fear feels like.
There's only negotiating what it means.
There's only negotiating whether or not you persist, whether or not you pause, or whether
or not you retreat.
So this is usually the point in the podcast where I think people start asking, okay, well,
there's the biology, there's the mechanism, there's the logic. How do I eliminate fear?
Well, it's not quite that simple, although by understanding the logic and the mechanisms
by which these circuits are built, we can eventually get to that place.
I do want to plant a flag around a particular type of tool or a logical framework around
a particular set of tools, rather, that we are going to build out through this episode.
And based on what you now know that the threat reflex gets input and it has outputs and it's subject to these top-down
processing events, these narratives.
You should be asking yourself, what sort of narrative should I apply to eliminate fear?
Well, first let's take a step back and it just acknowledged the reality, which is that
fear is in some cases an adaptive response.
We don't want people eliminating fears that can get them injured or killed, right?
The reason that the fear, threat, response, and reflex
exists at all is to help us from dying,
to help us from making really bad decisions.
It just so happens that a number of things
happened to us that are not lethal, that don't harm us,
but that harm us from the inside.
And I think that, and here I'm borrowing language
from an excellent researcher who's done
important work in this area at Harvard.
His name is Dr. Kerry Ressler.
He's both a medical doctor and a PhD,
so an MD PhD.
He's the chief scientific officer at McLean Hospital.
He's a professor of psychiatry at Harvard Medical School
and he's done extensive and important work on fear.
I'm going to refer back to Dr. Ressler's work
several times during this podcast, including
important and super interesting work on transgenerational passage of trauma.
He's a absolutely world-class biologist, absolutely world-class
clinician. And Dr.
wrestler has described fear before as containing a historical component.
So it's not just about a readiness for things
that might injure us or kill us in the immediate circumstance,
but also protecting us for the future
because of our important need and ability to anticipate.
And what he describes are memories as protective
or memories as dangerous.
Some memories, even if they evoke a sense of fear in us are protective
They protect us from making bad mistakes that could get us injured or killed or put us into really horrible circumstances
other memories are dangerous because they create a sense in us of
discomfort and they to limit our behavior in
of discomfort and they tend to limit our behavior in ways that are maladaptive, that prevent us from having healthy relationships to others, healthy job relationships, healthy relationship
to ourselves, frankly.
So this language of memories as protective or memories as dangerous in the context of
fear is not something that I said.
It's really something that I lifted from Dr. Restler, one of his many impressive lectures.
And it's an important aspect of fear because much of the fear system is a memory system.
It's designed to embed a memory of certain previous experiences in us such that the threat reflexes
activated in the anticipation of what might happen.
Okay?
So let's talk for a second about how certain memories get attached to this fear system.
And this brings us to a beautiful and indeed Nobel Prize winning aspect of biology and physiology,
which is Pavlovian conditioning.
Many of you are probably familiar with Pavlov's dogs and the famous Pavlovian conditioning
experiments.
They go something like this.
If you and Pavlov did these experiments and ring a bell,
a dog doesn't do much in response to a bell.
It might attend to it, but it doesn't salivate
typically in response to the bell.
However, if you pair the ringing of a bell
with a presentation of food enough times,
the dog will salivate in response to the food.
Eventually, you take away the food, you just ring the bell,
and the dog will salivate in response to the food. Eventually, you take away the food, you just ring the bell, and the dog will salivate in response to the bell.
Okay?
So in the context of so-called Pavlovian conditioning,
these things have names like condition stimulus
and unconditional and stimulus and responses.
People often get these mixed up
and it can be a little confusing,
but I'm just gonna make it really simple for you.
The unconditioned stimulus is the thing that evokes
a response unconditionally. So food is the unconditioned stimulus is the thing that evokes a response unconditionally.
So, food is the unconditioned stimulus, and the example I just gave, a foot shock or a
loud bang would be the unconditioned stimulus in, for instance, an experiment geared toward
exploring fear.
That unconditioned stimulus is unconditional.
It unconditionally evokes a startle, or in the case of food, salivating.
The bell in the previous example is what we call
the conditioned stimulus, or the conditioning stimulus.
Sometimes people mix these up.
The conditioned stimulus is paired with the thing
that naturally creates a response.
And then eventually the condition stimulus creates
the response itself. You might think, well, that just seems, you know, endlessly boring and simple,
but this is actually the way that our fear systems work. Except unlike Pavlov's dogs, you don't need
many, many pairings of a bell with some unconditioned stimulus in order to get a response, you can get what's
called one trial learning. And in this circuit that involves the amygdala, the threat reflex,
and all this other stuff that I was talking about earlier, the system is set up for learning.
It's set up to create memories and to anticipate problems. It's a very good system because it was designed to keep us safe.
And so the way to think about this is that for many people,
one intense experience, one burn, one bad breakup,
one bad experience, public speaking,
one bad experience with somebody's pet snake
or whatever it happens to be can cause intense fear in the moment,
a long, reverberatory experience of fear,
like trouble sleeping that night in the following night,
memories of the experience that are troubling,
physiological responses that are troubling.
Essentially, it gets wired in as a fear with one trial,
which is quite different than the other forms
of neuroplasticity, neuroplasticity,
of course, just being the nervous system's ability to change in response to experience. other forms of neuroplasticity, neuroplasticity, of course, just being the nervous system's ability to change in response to experience.
Other forms of neuroplasticity, like learning a language, learning music, learning math,
those take a while.
We don't generally get one trial learning to positive or neutral experiences.
We get one trial learning to negative experiences.
So there's this asymmetry in how we're wired.
So now you should understand how classical conditioning,
as it's called, occurs.
You go to give a piano recital as a kid,
you sit down and you freeze up,
and it's horribly embarrassing.
And even if you just freeze up for a few seconds,
the heart rate increase and the perspiring, the sweating,
and the shame that you feel leads
you to want to avoid playing instruments or public displays of performances for a long
period of time unless you do something to overcome it.
That's one trial learning.
Some people, it tends to be more an accumulation of experiences.
They have a bad relationship that lasts an entire summer, an entire year, or God forbid a decade.
And then they have what they feel is of a general sense of fear about closeness to others and
attachment. These are common fears that people experience. Fears can be in the short term,
fears can be in the long term, they can be in the medium term. Again, the fear system
is very generic. It's wired
to include memories that are very acute that happen within a moment, or that include many,
many events in long periods of time that kind of funnel into a general sense of, you know,
relationships are bad, or this particular city or location is bad. So there's a key,
what we call temporal component. There's a component
of the fear system being able to batch many events in time and create one specific fear,
or take one very specific isolated incident that happened very briefly and create one very
large general sense of fears. And I'll give an example of the latter just to kind of flesh this out a little bit.
I had a friend come visit me in San Francisco some years ago and their car got broken into.
Unfortunately, a frequent occurrence in San Francisco and being in the middle of the day.
Never leave anything your car in San Francisco. They'll break in in the middle of the day.
It doesn't matter. Police can be having coffee right there in front of them. They'll still do it.
For reasons we could discuss, this is a problem.
They got their belongings taken,
and they decided they were never coming back to San Francisco.
This was an isolated incident that forever colored
their view of the city, which I, you know,
frankly, understanding the fear system, I can understand.
We can have isolated incidents that
wick out to broad decisions about entire places,
or we can have many experiences that funnel into very specific
isolated fears about particular circumstances, places,
and things.
So I like to think that by now, you
have a pretty good understanding of the circuits that
underlie the threat reflex, the fear response,
and how we have top down control, meaning
we can attach a narrative to the fear response, and that the fear response can be learned
in association with particular events.
Okay.
I haven't really talked about how the learning occurs, and so I just want to take a moment
and describe that because it leads right into our discussion about how to eliminate fears and indeed how to replace fears with more positive experiences.
There's a process in our nervous system that we call neuroplasticity.
Neuroplasticity broadly defined is the nervous system's ability to change in response to
experience.
But at a cellular level, that occurs through a couple of different mechanisms.
One of the main mechanisms is something called long-term potentiation.
Long-term potentiation involves the strengthening of particular connections between neurons.
The connection sites between neurons, we call synapses, actually technically synapses are
the gaps between those connections.
But nonetheless, synapses are the point of communication between neurons, and those can
be strengthened so that certain neurons can talk to other neurons more robustly
Then they happen to be for and anytime we talk about a particular event the car the snake the public speaking the the trauma the horrible experience
Wiring into the fear system what we're talking about is a change in synaptic strengths. We're talking about neurons that previously did not communicate well
communicating very well. It's like going from a
old school dial-up connection or even an old-school telephone connection or more code connection of
communication to high-speed ethernet, okay, to a 5G connection. It gets faster, it gets more robust, and it's very, very clear.
That's what happens when you get long-term
potentialiation.
And long-term potentialiation involves a couple of cellular mechanisms that are going to
be relevant to our discussion about treatments to undue fear.
And I'll just throw out a couple of the names of some of those cellular elements right now.
The main one is the so-called NMDA receptor,
N-Methyl-D-Aspertate receptor.
And what this is, is this is a little docking site,
like a little parking slot on a neuron.
And when a neuron gets activated very strongly,
like from an intense event,
and the example of my friend, the intense event,
almost certainly activated NMDA receptors
related to their concept of
protecting their property and their cars.
The break into their car caused the NMDA receptor to be activated.
Normally that NMDA receptor is not easily activated.
When it is activated, it sets off a cascade, a series of signals within those neurons that
change those neurons.
It changes the genes they express.
It shuttles more parking spots to the surface of those cells so that the communication to those
cells becomes easier.
It becomes faster.
And so the way to think about the NMDA receptor is it's used sometimes for normal things that
we do every day making cups of coffee and things like that, but it's often used for learning.
It's used for creating new associations
in our nervous system.
And so the activation of the NMDA receptor and LTP,
and it involves some other things
that you may have heard of like brain derived
and atropic factors and calcium entry,
things that we can leave for a discussion
for a future time, but basically a whole cascade
of events happen within cells that then make
just even the mere thought of something or somebody or some event that happened able to
activate that threat reflex.
So long-term potentiation is one of the main mechanisms by which we take formally innocuous
or irrelevant events and we make them scary.
We make them traumatic. Our neurons
have mechanisms to do this. Now, fortunately, the NMDA receptor and long-term
potentiation can also run the whole system in reverse. You can get what's called long-term
depression, and that doesn't have anything to do with the depression associated with low mood.
What we're talking about is a weakening of connections.
You can go from having a very high speed ethernet connection between neurons, so to speak,
to a connection that's more like Morse code or is like a poor dial-up connection, a really
weak signal.
And that's what's happening when you extinguish a fear, when you unlearn a fear.
So now I'd like to talk about therapies that are carried out in
humans that allow fears to be undone, that allow traumas to be reversed such that people no longer
feel bad about a particular person place or thing, either real interactions with that person
place or thing, or imagine interactions with that person-placer thing.
That process, as I just mentioned, also involves things
like the NMDA receptor, but rather than strengthening
the connections, the first thing that has to happen
is there needs to be a weakening of connections
that associate the person-placer thing
with that threat reflex.
Subsequent to that, we will see,
there needs to be a strengthening
of some new experience that's positive. Okay. This is a key element of where we are headed.
Contrary to popular belief, it is not going to work to simply extinguish a fear. One needs to
extinguish a fear and or trauma and replace that fearful or traumatic memory or idea or response
with a positive response. And this is something that's rarely discussed, both in the scientific literature,
but certainly in the general discussion around fear and trauma. There's this idea that we can
extinguish fears, we can rewire ourselves, we can eliminate our traumas, and indeed
we can, but that process has to involve not just becoming comfortable with a particular
fearful event or trauma, but also attaching a new positive experience to that fear previously
fearful or traumatic event.
There are a lot of different approaches out there that are in clinical use to try and
alleviate fear and trauma and indeed PTSD, post-traumatic stress disorder.
It might be surprising to learn that many of those treatments, such as SSRIs, the selective
serotonin reuptake inhibitors, things like prozac and zoloft and similar, and other antidepressants,
or things like benzodiazepines, which are essentially like pain killers.
They create elevation in certain transmitters in the brain like GABA, among others.
They can have a pain relieving effect.
They are generally, however, considered angciliotics.
They reduce anxiety.
And even anti-psychotic drugs, or beta blockers, sometimes called adrenergic blockers,
drugs that are designed to prevent the heart
from beating too fast, or to reduce blood pressure,
to reduce some elements of that hypothalamic
pituitary axis response that we talked about earlier.
Many people experience some degree of relief
from the symptoms of anxiety and fear and PTSD in taking these various compounds. Indeed, that's why they're prescribed so broadly. But you may find it interesting to note that none of
those current treatments are based on the neurobiology of fear, at least not directly.
current treatments are based on the neurobiology of fear, at least not directly, right? People that take SSRIs oftentimes will experience a reduction in anxiety. It depends on the dosage
in the individual, of course, right? And you have to work with a doctor, a psychiatrist
to determine whether or not they're right for you and the correct dosage if they are
right for you. But that modulation of anxiety can indirectly reduce the likelihood that one will have a panic
attack or experience a fear and intense experience of fear or reliving of a trauma, but the SSRIs
themselves are not plugging into some specific mechanism related to how fear comes about in
the system.
It's an indirect support. That's important because if the goal of modern
psychiatry and the goal of modern biology is to provide mechanistic understanding that
leads to treatments, we need to think about what are the sorts of treatments that tap into
the very fear circuits that we described before. The fact that there are memories attached
to a generic threat reflex and response,
and the threat reflex response can be linked up with the dopamine system and can be linked
up with other systems that are involved in pain relief and anxiety and so forth.
And so that brings us to which treatments are directly related to the fear circuitry
and the circuitry related to trauma.
And the primary one to begin with is the so-called
behavioral therapies. Now oftentimes we all wish, I think, from time to time, that there's some
specific pill that we can take or there's some machine or device that we can plug our finger into
or that we can put on a headset and all of a sudden we just rewire a nervous system, fear is
gone, trauma is gone, but it doesn't work that way. And when we think of language and narrative as a tool to rewire our nervous system, in
comparison to those kinds of ideas about pills and machines and potions, it starts to seem
a little bit weak, right?
If we just think, oh, well, how could talking actually change the way that we respond to
something? just think, oh well, how could talking actually change the way that we respond to something.
But actually, there are three forms of therapy that purely through the use of language have
been shown to have very strong positive impact, meaning reduced fears and traumas.
And those three are prolonged exposure therapy, cognitive processing, or CPT, and cognitive
behavioral therapy.
And I'm not going to go into the entire literature around prolonged exposure, cognitive processing
and cognitive behavioral therapy, but I will just illustrate the central theme that allows
them to work.
Now, remember that the circuit for fear, the circuit for trauma involves this generic reflex,
and then there are those top-down elements coming from the forebrain.
It's very clear, because it's been measured, that if you look at the amount of anxiety,
the pure physiological anxiety response of quickening of heart rate, blushing of the skin,
sometimes quaking of the hands, the experience of fear, over time,
when people recount or retell their trauma,
that the first time they do that,
especially when it's recounted in a lot of detail,
there's a tremendous anxiety response.
Sometimes even as great or greater
than the actual exposure to the fearful event or trauma.
And obviously this is something that is done with a clinician present because it is very
traumatic to the person.
They're literally reliving the trauma in full rich detail and they are encouraged to provide
full rich detail.
They're often encouraged to speak in complete sentences, to flesh out details about how they felt
inside, to flesh out details about their memories going into this traumatic or fearful event,
going through it, and after really digging into all the nuance and contours of these horrible
experiences.
But what's remarkable is that in the second and the third and the fourth retelling of
these traumatic or fearful events, that anxiety response and the amount of the physiological
response, I should say that the amplitude of the physiological response becomes progressively
diminished with each retelling.
Now some of you might be saying, well, duh, you know,
you tell a story enough times, you know, that eventually it wears off. Just like if you watch
a movie enough times and you hear the same joke enough times, eventually it doesn't have the same
impact. But that mean be the case, right? You could imagine that this high amplitude anxiety response,
this high amplitude activation of the sympathetic nervous system in retelling would actually create a even deeper,
routed fear response in trauma. But that's not what happens. And every clinician I spoke to in anticipation of this episode,
which include clinical psychologist, psychiatrist, and people who actually work on the fear system at a biological level said the exact same thing, which is that a detailed recounting of the traumatic
and fearful events is absolutely essential in order to get the positive effects of prolonged
exposure, cognitive processing, and cognitive behavioral therapy.
Again, this has to be done with the appropriate support.
This isn't something that should be taken lightly because, you know, as we've mentioned before, the
fear response can have a very long lasting contour to it. People can sometimes have trouble
sleeping for days and days. Afterwards, we'll talk about sleeping a little bit. But the
point is that the retelling is important. And the idea here is to take what was a terrible and extremely troubling,
meaning physiologically troubling, psychologically troubling story, and turn it into what is essentially
a boring, bad story. Okay. It never really becomes a good story at this point in the treatment
process that we're describing.
So a terrible event is a terrible event period, but there's a way in which the retelling of that
event starts to uncouple the threat reflex from the narrative. And with each successive
retelling in detail of these traumatic events, of these fearful events, the threat reflex is activated
at a progressively lower and lower amplitude, such that eventually it just becomes a really
bad, really boring story.
Now that's one part of the process of getting over a fear.
It's what we call fear extinction.
And we can bring ourselves back to our earlier
example of Pavlovian conditioning because many studies have been done, both in animals and in humans,
showing that, for instance, if you pair a tone, you know, a beller a buzzer with a foot shock,
that an animal or a person will brace themselves for the foot shock.
Eventually, you can just give the bell or tone
and the person will experience that same freezing up
or that same fight or flight or freeze response.
So you condition that.
But if you give the tone or the bell over and over
and there's no foot shock, there's no pain.
And in humans, this is sometimes on with foot shock,
sometimes I'm, believe it or not, with mild burn.
There are even some studies, there's older studies,
you couldn't do those now nor would
you want to.
But eventually what happens is the tone, the bell, no longer evokes that response.
So you see this as a reversal of the classical conditioning and we call that reversal extinction.
So the retelling of this traumatic or fearful narrative, excuse me, fearful narrative, is
essentially an extinction process.
Now how is this done?
One can do this in a therapist's office face to face, that's sometimes done.
It's sometimes done in group type settings where people actually stand up or sit in front
of a group smaller large and recount in detail their traumatic experience.
It's sometimes done by people writing out the experience in detail.
And which one of these is most effective isn't really clear.
The literature points to the fact that a feeling of trust obviously between the patient
and the clinician or the person and the group is essential.
Some people don't
access to because of finances or other limitations. To therapy of that sort, in that case, journaling
in detail has been shown to be effective. Although, again, I want to caution people about
reactivating traumas without consideration for the kinds of social support they might
need around that reactivation. And we will talk a little bit later about some of the chemicals involved in social support
and why those help extinguish fears.
So the thing to embed in your mind is that recognition
of the early traumatic or fearful event in detail
over and over is key to forming a new
non-traumatic association with that event or person.
So that's part one.
You need to diminish the old experience.
And when I say diminish, I mean reduce the amplitude of the physiological response.
Now this is just but one approach.
I'm going to talk about other approaches to eliminating fear and trauma as we go forward.
But I want to emphasize that diminishing the amplitude of the physiological response is
the first step.
So it's like a clearing away of the association between the person, place, or thing,
and that threat reflex.
But even after that's occurred, there's an essential need to relearn a new narrative.
Why is there essential need to relearn a new narrative. Why is there essential need to relearn a new
narrative or create a new association? Well, that has to do with that fear reflex circuitry.
As you recall, there are outputs to areas of the brain that are associated with dopamine
release and reinforcement. And that we now know offers the capacity for these fear circuits and these circuits that underlie trauma
to be mapped onto new experiences
that are of positive association.
So I'm gonna give a kind of basic example.
It's kind of a silly example,
but I'm giving it as a template
for what could be any number of other different examples.
Example I'll give is let's say a kid is biking
to play soccer, soccer practice,
and they get into a bad car accident, okay?
Terrible thing to happen, but they survive, they recover.
And somehow, and we really don't know why certain
fear memories get wired in more broadly or more narrowly.
Somehow this kid just doesn't even want to bicycle anymore and they actually don't even want
to play sports and they actually just don't want to go anywhere.
They're kind of isolating and not interacting with friends very much at all.
It's a pretty broad response.
It didn't have to be that way.
Some kids would just decide they don't want to cycle anymore down that particular street.
Well, the process of retelling the narrative to a clinician would
allow an extinction of the fear response, right?
So a reduction in the heart rate, a reduction in the narrowing of focus, a reduction in all
the things that we consider fear, but a really good cognitive behavioral therapist or somebody
that understands the neuroscience of fear and trauma would understand that that's not sufficient.
That's what's really important is that this child,
this hypothetical child, relearn a new narrative
that they don't just manage to bite to soccer practice
or manage to spend time with friends,
but that they actually start wiring in new positive associations
with biking to practice, with playing soccer, with social events.
And, and this is the somewhat surprising feature of this, and that they link that back to that early traumatic experience.
That it's not just that they're
replacing at bad experience and memory with a good experience in memory, but they're actually holding in mind
in these top-down narrative circuits, if you will.
They're holding in mind, ah,
I'm not just biking to soccer practice.
I'm actually biking to soccer practice
and I'm enjoying it despite the fact
that I was in a bad car accident.
Despite the fact that two months ago or two years ago
or maybe even 10 years ago,
I couldn't even leave my room
or I didn't want to associate with anybody.
So the building up of the positive associations are key.
And the linking of those positive associations with the earlier traumatic event is key for
the following reason.
The top down circuitry from the prefrontal cortex to this threat reflex circuit is not like the other
connections in that circuit. The other connections in that circuit are what we
call glutamatergic and excitatory. They are all about activating other neurons,
like a chain reaction. One neuron activates, the next activates, the next like
dominoes falling. These top-down circuits that feed into the threat reflex and all its parts is what we call
inhibitory.
It tends to prevent activation of those given circuitries.
It tends to prevent activation of the threat reflex.
So it's acting as a break.
And so when we think of positive experiences being associated with what was previously
a negative experience, we're not talking about forgetting that the car accident was horrible
or forgetting that the assault was absolutely dreadful. We're talking about attaching a
new positive memory to the circuitry so that the previous fear response is far less likely to occur and that it remains
extinguished.
So just to make sure this is absolutely clear, there's a first step which involves
retelling and reliving in order to extinguish the fear and the trauma, to reduce the amplitude
of the response.
Then there's a need to replace or attach positive experiences to the earlier
what would be traumatic response.
The extinction has to go first.
This is key.
You can't simply say, oh, you know,
the car accident was actually a good thing
because I stayed home a lot that year
and I got to study.
You can tell yourself that and that could also be true,
but that won't necessarily and probably won't
eliminate the fear or the traumatic association of the car accident.
And again, I'm using car accidents as a general example or generic example here. Okay, so there's
the three part process. One, diminish the old experience through repetitive narrative. And almost
inevitably the initial repetition of that is going to be very high amplitude and quite troubling,
but over time it will reduce. You're turning the terrible, really upsetting story into a terrible
boring story. That's the extinction process. Then there's a relearning of a new narrative that
includes some sort of sense of reward, and that sense of reward has to be tacked back onto
the traumatic event, or what was previously a traumatic event.
And that is all through narrative.
It's all through cognition.
And I think this is a very important point.
Oftentimes I think we tend to undervalue the importance of rationalization and of story
and of narrative.
But the prefrontal cortex is this amazing capacity of our brain real estate to
create meaning, to attach meaning and purpose to things that otherwise are just reflexive.
And in the example of an ice bath, it might be a little trivial. In the example of the
kid with the car accident, it becomes a little more relevant. And in the example of things
like people surviving, you know, genocide or attaching stories of, you
know, of great victory to what were previously thought of as stories of great loss, of time,
of people, of any number of things, that process of narrative is one of the major ways that
the human brain rewires itself.
Narrative should not be undervalued as a tool
for relieving fear and trauma.
In fact, narrative is one of the best and most potent ways
that we can rewire our fear circuitry,
and that indeed we can form completely new relationships
to things over time.
So basically, narrative should not be undervalued
as a tool to rewire our nervous system,
but it has to be engaged in the correct sequence. And that correct sequence is first extinction,
then relearning a new narrative with positive associations and attaching those positive associations
to the formerly traumatic or fearful event. Now, I mentioned prolonged exposure therapy,
cognitive processing and cognitive behavioral therapy.
For those of you that are seeking relief from fear and traumatic events, you can look up
license clinicians that can carry out those one or several of those types of therapies.
I get a lot of questions about other forms of therapy.
One of the ones that comes up a lot is so-called EMDR. I move in desensitization
reprocessing, developed by Francine Shapiro in the 80s. I move in desensitization reprocessing,
involves moving the eyes side to side while recounting a traumatic or fearful narrative,
typically with a clinician present. Why would that work? Well, basically, when I first heard about EMDR,
from my stance as a vision scientist, I thought the whole thing was kind of crazy and half-baked.
Frankly, I heard these theories that, oh, it recreates the eye movements in rapid eye
movement sleep or REM sleep, and that's completely false. It does not. I heard the argument EMDR activates both sides of the brain,
which I guess hypothetically was thought to be important somehow.
And frankly, there's no evidence whatsoever
that EMDR activates both sides of the brain in a way that's beneficial.
I mean, by looking from side to side just because of the way
that binocular visual circuits are organized, it will do that.
But it never made any sense to me why EMDR would work until several years ago when I saw
because I reviewed no fewer than five papers, some in animal models, others in humans,
looking at lateral eye movements, meaning eye movements from side to side with eyes open,
not eyes up or down, and what was observed in these experiments, in all of them actually, all five of those
papers was a dramatic reduction in the activation and actually inhibition, a suppression of
the fear or threat reflex circuitry, which was a jaw dropper for me.
I thought, wow, she was a jaw dropper. I widen her for me. I thought, oh my goodness,
maybe this EMDR stuff works
according to some mechanism, and maybe this is the mechanism. And indeed many laboratories, not mine,
but many laboratories are now pursuing that idea, and it's looking very likely. Why would that happen?
Well, just very briefly, a lateralized eye movements of the sort that I'm describing,
and I'm moving my hand like this, but I'll just do it with my eyes, even though it's a little embarrassing to do that,
because I know it looks strange, I don't mind, because I'm doing EMDR, and EMDR reduces activation of the amygdala and related circuitries,
which reduces anxiety, and reduces the amplitude of the threat reflex.
Reduces sympathetic autonomic arousal.
In other words, we feel calmer or we feel less alert, less stressed when moving our eyes
from side to side.
And the just so story about this is that these are the sorts of eye movements that we do when
we are ambulating, moving through space, through some sort of self-generated motion. One can make up a pretty reasonable story
in the evolutionary context or ethylogical context that forward movement and fear are generally
incompatible with one another. That generally a fear response involves a freezing or a retreating.
Some people will advance, but that's usually a trained advance in response to fear.
So first responders and so forth.
Most people freeze or retreat when they're afraid.
Forward movement generates these eye movements.
It does seem to suppress activation of this threat reflex and the amygdala in particular.
So for the many EMDR practitioners out there, these papers, I think, are a great celebration,
and I think there is now increasing excitement about EMDR in the psychiatric and psychological
community for its utility for treating fear trauma and PTSD.
However, I should point out that in discussing EMDR with various colleagues of mine at Stanford
and elsewhere, I was told that EMDR has been shown to be beneficial in particular for
single event type traumas or fearful experiences.
Not so much for relieving the trauma or feelings of fear associated, for instance, with an entire
bad marriage or an entire childhood, but more for single,
more acute events that can be described within a very brief narrative.
Brief not necessarily in time, but that the car accident, the bad interaction with another
individual, the assault, God forbid, the assorts of things.
And I realize we're down in the weeds of topics that are unpleasant. And so I have
great sensitivity to that. But I think it's also important that we be realistic about
the kinds of things that traumatize people. So is EMDR useful? Well, it seems like it works
for these single event or kind of constrained event type traumas that people can describe
while moving their eyes from side to side, generally in the presence of a clinician.
However, if we think back to the model of how you extinguish and then replace a trauma or
fear, remember you have to diminish the old experience, the amplitude of that, you need
to, that's the extinguish portion, then you need to relearn a new narrative and attach reward to the old traumatic event.
EMDR only really taps into the extinction of the physiological response to the old experience.
I'm sure that there are EMDR practitioners out there that are thinking about the attaching
of the new narrative and reward, but there I've heard less,
and I've seen fewer peer-reviewed papers on that.
So let's think about this logically.
Let's say, and indeed, it's the case,
that sitting down in a chair,
moving eyes, side to side deliberately
for some period of time,
reduces activation of the threat reflex.
I or the patient, in this case,
recites or repeats over and over the traumatic event or
the fearful event.
I'm doing that in the presence of a lower amplitude response.
Remember back to where we talked about how the retelling works best.
If the first time it's done, there's a huge amplitude response. And then with each
successive repeat, the threat response gets lower and lower. With EMDR, you're sort of short
circuiting. You're kind of sneaking around the corner of that high amplitude response. And so
you're taking a somewhat different approach of trying to extinguish the bad feelings in body and mind, associated with an experience by reducing
the physiological response.
So it's somewhat different, and at least to my knowledge, and EMDR practitioners, please
correct me, but at least to my knowledge, there isn't an active component to EMDR of
relearning a new narrative and attaching reward.
Now reward and attaching reward requires a somewhat high amplitude sympathetic arousal.
It requires a feeling of a victory, which is arousal.
Okay, it's positive arousal, not negative arousal, but it is arousal.
So I'm not focusing on this to try and diminish the potential impact of EMDR.
I know many people have achieved
great relief from EMDR, but it doesn't tap into all the aspects of the extinction and relearning
that we talked about previously. And therefore, I think on its own, at least in many cases,
is unlikely to be a complete therapy for fear and trauma. If there are people out there who've had
terrific results with EMDR, please let us know
in the comments section on YouTube would be the ideal place.
If you've had bad experiences with an EMDR or it didn't work for you, also let us know.
I think that EMDR practitioners, like most practitioners in the psychiatric and psychological
space, are eager to expand their practices in order to make them more effective rather
than clinging
ardently to something that perhaps is incomplete or that doesn't work for certain individuals. So I think they would appreciate that feedback as would I. So as I mentioned before,
most of these therapies are done in conjunction with a skilled often, one would hope,
credentialed clinician. There are many people, however, that don't have access to that, or who are working
through stuff. They have things in their past that are very uncomfortable to them, and
I'm aware that many people are working through those things through journaling, through
talking to a friend, through any number of different sort of non-traditional approaches. One
thing that really pertains to everybody who's working
through fear and trauma of any kind is the importance of social connection as it relates to the
chemical systems and the neural circuits associated with fear and trauma. And this is a emerging
literature in neuroscience that is really a beautiful one because it's a very conserved biology. We see it believe
it or not in flies and fruit flies commonly used model system in mice and indeed in humans as well.
And this is the work of David Anderson's group at Caltech of again of Dr. Restler's group at Harvard
Medical and elsewhere of course. And this is the work as it relates to tachykinein.
Tachykinein is a very interesting molecule in our brain.
And it turns out the tachykinein is
activated in neurons of what's called the central amygdala
and some nearby structures.
So really smack dab within the middle of this threat reflex very soon after
some traumatic or fear inducing event occurs. And it actually sets in motion a number of
other things including changes in gene expression and potentiation meaning long term potentiation,
activation of NMDA receptors and so so on, in the circuits that reinforce
that fearful or traumatic experience.
Now, what's interesting about Tachykainin is also that it's been shown to lead to low,
to moderate levels of anxiety and even kind of aggression or irritability.
Tachykainin levels are further increased by social isolation.
And that social isolation is oftentimes what can exacerbate pre-existing traumas or
fearful events.
And in a kind of beautiful symmetry to that kind of dark and depressing story, social
connection with people that we trust, and it doesn't have to be direct physical contact,
but just social connection,
conversing with, sharing a meal with,
it could be physical touch if that's appropriate.
Those sorts of connections actually serve to reduce
the effectiveness or even the levels of Taki Kainan.
So the important point here is that,
trauma is traumatic in and of itself.
Fearful events are hard in and of themselves.
And if people are working through them either
through clinical work or through individual work,
it is important and ideally, one would still
be trying to access social connection outside
of that specific work related to the trauma.
Now it doesn't necessarily have to be outside of that.
For instance, if you have a good relationship with a clinician or therapist to the point
where there's real trust and you feel a social connection with them, wonderful.
But for many people, they have a more transactional relationship to the EMDR practitioner or to their therapist or they're
working through things on their own.
And it's really important to understand that regular social connection, trusting social
connection of any kind, is going to be very beneficial for that process.
And so this is not kind of just hand-wavy new AG stuff. Like, oh, you need social connection.
There's an actual neurochemical basis
for social isolation that has an amplifying effect
on fear and trauma.
And there is a neurochemical basis
for the relief from fear and trauma and isolation.
And in the ideal circumstance, one is working through
these traumas and fears very intensely
in a very dedicated way. But then is also engaging in the sorts of social interactions that are going to diminish
the amount of tachychin and going to suppress those very circuits that would otherwise be
amplified.
So next I'd like to talk about some really interesting and almost kind of eerie scientific
findings, and that's the transgenerational passage of trauma
or predisposition to fear and trauma.
This is a scientific literature that's been debated many times
over the last really 50 plus years.
But in more recent studies,
have really proven that we as humans
have the capacity to inherit a predisposition to trauma or fear.
Now that doesn't necessarily mean that we will become traumatized or experience extreme
fear just because our parents or grandparents experience that.
It's a predisposition.
It's a bias.
Let me explain the papers that focus on this for a little bit, and then we'll talk about
what this means for each of us.
One of the most important papers in this area comes to us from someone I mentioned earlier,
Dr. Kerry Restler at Harvard.
The title of the paper is Association of FKB5 polymorphisms and childhood abuse with risk
of post-traumatic stress disorder symptoms and adults.
And there are other papers as well.
Another one from the Restler Lab, first author, Brian D.S., D-I-A-S, parental factor experience
influences behavior and neural structure in subsequent generations.
I'm going to summarize these papers in their general contour and papers related to them,
although feel free to look up the papers I just described.
We will provide a link to them in the caption if you'd like to go further.
But basically these explorations involve looking at the histories of human individuals
who had trauma or abuse of some kind in their childhood and then looking at the likelihood
of fear and PTSD type symptomology in their
offspring.
And essentially what they identified is that indeed, if you had a parent and there does
seem to be a kind of a bias toward an effect where if the father had abuse and its severe abuse or moderate abuse, that abuse causes a change in his genetics, in his sperm,
that can be passed on to offspring such that the offspring have a lower threshold to develop
trauma or extreme fear to certain types of events. Now what's important to point out is that predisposition or bias is not necessarily to the
same sorts of events.
It's not that the abuse itself gets passed from one generation to the next.
It's a predisposition.
The title of that paper mentioned, FKB5, excuse me, FKBP5 polymorphisms, and the FKBP5 polymorphism maps to a location
in the genome that's associated with the so-called gluteocorticoid system, with cortisol
release.
So the predisposition that one might inherit from having a parent, father or mother,
but stronger tendency to inherit it from the father,
who experienced abuse, is one in which the glucocorticoid system,
the cortisol system, and that HPA axis that we talked about
before, the hypothalamic pituitary adrenal axis,
is sensitized or reactive in a way that sets a lower threshold
to become traumatized or very afraid of certain
types of events.
But it's not unique to the specific type of abuse that the parent experienced.
This is really, really important because a lot of times out there, I will hear that there's
passage or transgenerational passage of actual trauma, the specific trauma.
Now that could be through narrative telling,
you know, if somebody is exposed to a lot of narrative about their parents trauma in
one form or another, it may be that they start to internalize some of that trauma. And
there could be, because obviously we can't rule it out, there could be some other signatures
of prior specific traumas they get passed on to offspring. But more likely, and certainly what these data about these polymorphisms point to, is that
what gets passed on is a propensity for the threat reflex to get activated and attached
to a wider variety or to less intense types of inputs and experiences.
And the important point to take away from this is that it's not some magical, mysterious
and mystical thing that's being transplanted from parent to child, it's a gene or it's
a modification in a set of genes that gives a heightened level of responsibility to fearful type events, or
even a heightened level of responsibility such that things that wouldn't be fear-inducing
or trauma-inducing to certain individuals can trigger fear and trauma in these children
that inherit this particular gene.
Now that doesn't necessarily mean that they are faded to forever be traumatized or live
in fear, but simply not the case.
It's just a genetic predisposition.
Regardless of whether or not you had a parent or parents that were traumatized or not,
there's no evidence, at least as far as I'm aware, that the treatments for trauma should
be any different.
As far as I know, there aren't gene therapies currently aimed at these particular variants
like FKBP5 and so forth that could reverse those particular genetic underpinnings of the
trauma predisposition.
So this transgenerational passage of trauma, I think, is extremely interesting in large
part because it brings us back to this idea that the threat
reflex is part of a larger sensory system.
Normally we think of seeing as a sensory system or hearing as a sensory system, but the threat
detection and threat learning system, the fear learning system, is in many ways a sensory
system.
It's just a sensory system that is very generic in its response.
That generic
response again is good because it allows for flexibility, but it's bad because it reduces
specificity, right? We can essentially become fearful or traumatized by anything if the
circuit gets activated. And these particular children inherit a predisposition for more things
and less intense things to traumatize them. In a few minutes we are going to discuss
some of the behavioral treatments, including some really new exciting protocols for dealing
with fear and trauma. But for a few minutes I'd like to discuss some of the drug treatments
that are starting to emerge as potential therapeutics in particular for PTSD. The two drug treatments
I'd like to focus on are ketamine assisted psychotherapy and MDMA
assisted psychotherapy. Currently ketamine assisted psychotherapy is legal. It is approved, provided it
is prescribed by a board certified physician in the United States. I'm not certain about other areas
of the world. MDMA also sometimes called ecstasy therapy, is in clinical
trials in the U.S. it is still an illegal drug to possess or to sell. So I want to be very
clear about that. However, MDMA is being explored as a potential therapeutic for PTSD and other
forms of trauma. And of course, ketamine and MDMA are also both being explored
for chronic depression, eating disorders,
and a number of other psychiatric disorders.
But for the moment, I just like to touch on ketamine and MDMA
as they relate to the fear circuitry and trauma circuitry
that we've described in the early part of the episode
and throughout the episode, because I think that in viewing them through that lens, we
can gain some additional insight into how they might be providing the sorts of relief
that some of the early clinical studies are starting to point to.
Ketamine is a dissociative anesthetic.
That's right.
It's a dissociative anesthetic.
It's main function is to create a state
of dissociation. And I've never taken ketamine personally, so I can't describe the experience of
it, but a colleague of mine in psychiatry shared their experience with a patient's experience of it,
as making that patient feel as if, quote, they were getting out of the cockpit of a plane,
but that they were observing themselves doing it. And this was, of course, during a approved
therapeutic session that they were doing this. And they were in some sort of intense visualization
about a traumatic experience. They were describing some of their depressive symptoms, as well as the trauma,
and their narrative that they basically created
or took away from this, and that was related to me,
was one in which the patient felt like they were in their own body,
but they were also viewing their own body from the outside.
So dissociative, in other words,
again, I've never had this experience.
Some of you may have with ketamine or through other means,
but we might want to just take a moment and think about what ketamine actually does and what
dissociation actually does at the level of neural circuits. For that, we can look to this really
beautiful paper that was published by my colleagues Carl Dyseroth in psychiatry, Robert Malenka, also in psychiatry, Legion
Low, also at Stanford.
They paired up or teamed up, rather, to explore how systemic ketamine adjust circuitries
in the brain.
What they discovered was that it changes the rhythm of cortical activity in certain layers
of the cortex.
The cortex is like a layered sandwich.
The cortex is being the outside of the brain. And there was a particular rhythm. A 1-3
hurts rhythm. 1-3 hurts just means a particular frequency of electrical activity. In this
case, in these layer 5 neurons, a retro-splineal cortex. So you don't need to know much about
retro-splineal cortex or one to three hertz rhythms.
I think the important thing to just take away from this is that there is now starting to
be an understanding of how drugs like ketamine work to create this subjective experience that
this patient and other patients describe as dissociation. You know, dissociation in its essence is really about not feeling what's
happening. It's about viewing what's happening from a different perspective than what normally
one would view that experience from. And so if we kind of plug that general notion of dissociation
and ketamine-induced dissociation into the circuit that we talked about before,
where we have this threat reflex involved in the amygdala, these outputs for freezing
or for reward in the incumbents, and we've got this prefrontal narrative coming down as top-down processing.
It brings us right to that prefrontal cortical input to the threat system and that narrative.
What seems to be the case in my review of the paper I just
described plus a review on how ketamine assisted trauma
relief might work is that it somehow
allows the patient, the individual, to recount their trauma
while feeling either none or a very different set
of emotional experiences that they experienced in the actual trauma or fearful experience.
So it's a remapping of new onto old, new meaning new feelings onto old feelings while staying in the exact same narrative.
So it's a little bit like EMDR of suppressing the threat reflex, but it seems to bring in a replacement of previous emotional
experiences and sensations in the body with new ones. And so in that way, we can sort of view,
or we can try and view ketamine assisted psychotherapy for the treatment of trauma as bringing
together the three elements that we talked about before. You want to diminish the intensity, the potency of the old, original trauma experience or
fear experience.
So that seems to be accomplished through this dissociation and maybe through the kind
of anesthetic component.
So it's a reduction in pain in the body, dissociation, a kind of observing of the self.
That leads to the extinction of the trauma and the fear.
But then there also seems to be an automatic or kind of built-in relearning of a new narrative
and new set of experiences, which is the next step that we described earlier.
So it's an intriguing therapy.
It's one that's really catching on and there are many, many clinics around the U.S. that
are now doing it. Whether or not it turns out to be the ultimate treatment for trauma and for fear.
I isn't clear. My colleagues in psychiatry tell me that that's unlikely,
although it does seem to be beneficial for a number of people,
especially people that are experiencing trauma or have existing traumas and fear
that are coupled with depressive symptoms because the data on ketamine
and depression seems to be quite strong. So now let's talk about MDMA. MDMA also sometimes called
ecstasy or molly in its recreational form is a powerful synthetic drug that at least as far as
we know creates a state in the brain and body that is unlike any other
chemical state in the brain and body that's normally experienced. What do I mean by that?
Well, we have several neuromodulator systems in our body. Neuromodulators are chemicals that
change the likelihood that certain neural circuits will be active, meaning they can make it
very likely that certain circuits will be active and make it very unlikely that other neural circuits
will be active. Good examples of neur that other neural circuits will be active.
Good examples of neuromodulators are dopamine, serotonin, acetocholine, norepinephrine.
These tend to work on different systems in the brain and body, but they tend to be activated more or less in parallel.
You can have dopamine released in your brain and also norepinephrine.
You can have serotonin released in your brain and also acetocholine, so it's not an all-or-none kind of thing,
but the degrees to which these things are activated tends to vary.
And there is a little bit of a seesaw type phenomenon
with dopamine and serotonin, dopamine most commonly associated
with activating neural circuits related to motivation,
craving, and reward.
And serotonin, more typically activated in response to situations or conditions in which we
are very happy and content with what we have.
So dopamine is more about pursuing and seeking.
Serotonin is more about kind of pleasure and satisfaction with resources that we have
in our immediate sphere.
They don't tend to, serotonin doesn't tend to place the brain and body into a mode of action quite as much as dopamine does.
More or less.
MDMA is a unique compound in that it leads to very large increases in the amount of both dopamine and serotonin in the brain and body simultaneously. And that's a unique circumstance that is just simply not seen under normal conditions.
From a subjective standpoint, people under the influence of MDMA in the therapeutic setting
tend to report immense feelings of connection or resonance with people or even things with music with objects.
Certainly, if it's being done in conjunction with a family member or a partner or with a therapist,
they will feel extremely connected to that person.
They'll feel a very close understanding and association, oftentimes, that goes beyond words.
There is a chemical reason for that. It turns out that MDMA causes massive
release of oxytocin, this neuropeptide that's associated with pair bonding and with bonding generally.
The oxytocin system and the serotonin system are closely linked to one another in the
brain and body, and they tend to be co-released often at the same time and by the same sorts
of events.
So MDMA is one mechanism by which oxytocin is released in these massive amounts.
And I should just relay some of the levels of oxytocin because they're really quite striking,
gives a more vivid picture of why it is that MDMA would make people feel so associated
in a positive way with the various things that are happening to them while they're under
the influence of the drug.
The paper related to this that I'd like to highlight is in the journal Psychonero Endocrinology,
the title of the paper is Plasma Oxytocin Concent concentrations following MDMA or intranasal oxytocin in
humans. And just remarkably MDMA increased plasma oxytocin levels to 83.7, this is an
average, 83.7 pg per milliliter, about 90 to 120 minutes into the MDMA session compared to a typical level of 18.6.
So this is a massive increase in oxytocin.
And I think that massive increase in oxytocin is part of the reason why people have these feelings of close resonance and association.
Now, the dopamine increases are generally what lead to the feelings of euphoria inside of the
MDMA session, and then the serotonin increases, it is thought, or what lead to the feelings
of safety and comfort.
So again, a very unusual chemical cocktail that would never be seen at least not at this
amplitude under any normal conditions outside of an MDMA clinical psychotherapeutic session.
Why would this state of mind and body
be potentially useful for the treatment of trauma?
Well, indeed it is revealing itself
to be useful for the treatment of trauma.
Again, these are legal clinical trials
where people are doing this and discovering this.
What it seems to allow is a very fast relearning or new associations to be tacked
on to the previously traumatic experience. So again, it brings us back to the
same model of how people extinguish fears and traumas and replace them with new
experiences when there is no drug treatment involved. There needs to be a diminishing of the old experience,
meaning an extinction and then a relearning of a new narrative.
What the chemical milieu of MDMA seems to be doing is creating an opportunity
for all that to happen very fast without the need for many repetitions
of the original trauma and reliving of the original trauma,
probably because the reliving of it inside of one of these MDMA sessions
is very acute, very intense,
plus it seems to be offering the opportunity to extinguish and rewrite in,
or write in a new narrative associated with that trauma very quickly as well.
So what this means is that treatments like MDMA
that are under investigation in these clinical trials
are unlikely to be magic potions, if you will,
that allow access to a particular process
that would otherwise not be accessible.
It's more that the typical process of trauma and fear reduction that's carried out in things like prolonged exposure, cognitive process, and cognitive behavioral therapy,
seems to be compacted into a much shorter session, and that session is performed at a much higher intensity.
Higher intensity because the chemical of milieu of the brain is completely different. I mean, the experience of MDMA is one in which people have a very
heightened sense of euphoria, a very heightened sense of connection. So those positive experiences
are essentially primed to be written in and over the traumatic experience. And because
of the high levels of serotonin in the system, and probably oxytocin as well, there's
a safety that's written into the situation that allows people
to lean into perhaps narratives or components of narratives that they would otherwise be
holding back from.
So these are powerful compounds, and I think the future of MDMA assisted psychotherapy
for trauma in particular is holding great promise.
As of now, meaning at the time of the recording of this podcast, again, I want to reiterate that these are clinical trials
are being done legally.
These drugs are still illegal to possess or sell
outside of clinical trials.
Doing this sort of thing is punishable.
But it does seem that the FDA and some of the related bodies
that control these sorts of things or eyes open to this stuff.
And I think it's very likely in the next few years things like MDMA and certainly ketamine
is already in widespread use within the psychiatric community.
And I think we're going to be seeing a lot more of that.
One thing we have not touched on yet is how do you know if you're traumatized?
How do you know if you have chronic fear
or a debilitating fear?
You know, much of the psychiatric community focuses
on how many other problems people might have, you know,
trouble sleeping, trouble eating,
trouble maintaining quality work or school work and so forth.
And all of those are certainly very valid criteria, necessary criteria for determining whether
or not somebody meets clinical diagnosis or not.
But there's a biological component that I think we can all assess for ourselves.
And that's one of interreceptive versus exteroceptive balance.
And that sounds confusing, but it's actually really easy to understand.
We can focus our perception on the external world events going on around us
beyond the confines of our skin or within the confines of our skin.
A focus and a perception on the external world is what's called an exteroception
and a focus on what's happening inside us is interoception.
And we have the capacity to build mental appraisal
into that, right?
I can, for instance, stop for a moment and assess
how my stomach feels, how hungry I feel,
how quick my heart is beating.
Some people, by the way, are much better at sensing
whether or not their heart is beating at a particular rate and others not so much.
Some people can actually count their heart beats without having to take their pulse by
placing pressure on their wrist or their neck.
Some people can't.
In other words, some people have very high interreceptive awareness and other people less so.
This whole business of fear and trauma relates to taking external experiences and funneling
those experiences into this thing that I'm calling a threat reflex or the fear circuitry.
A recent paper published in the Journal Science, so absolutely spectacular journal, science,
nature and cell being the apex journals of scientific publishing.
Get set this issue of where in our mind and how do we assess whether or not what we are
feeling internally is reasonable given what's going on externally.
And it's a really fascinating study.
I'm just going to highlight a little bit of it for you.
And then I'll touch on some of the relevant aspects
and how that can be adopted into a practice
to assess and reduce fear and anxiety.
The title of this paper published just a few weeks ago
in science is Fear Balance is maintained
by bodily feedback to the insular cortex in mice.
We've not talked too much about the insula,
also called the insular cortex.
This is a brain area that my lab has worked on and other labs have worked on. It's a brain
area that has within it a map of our internal interoceptive landscape. It's a map of our
internal bodily sensations. That's a really interesting structure. So the way this study was carried out
is that subjects were taught or conditioned
to a particular danger signal
through repeated presentation of a sound with a foot shock.
So there's a sound and there's a foot shock.
And as you know from our earlier discussion
about Pavlovian learning,
conditions stimuli and unconditions stimuli,
eventually the sound alone comes to evoke the fear response.
And that's just classical conditioning.
The insula is this brain area that's associated with
determining whether or not one's internal sensations,
gut, heart, lungs, et cetera,
are reasonable or not given the external circumstances.
It can even measure or is associated with our understanding of what are called atrial
barrel receptors.
These are blood pressure sensors.
So believe it or not, when your pulse rate increases or you feel like you're stressed
out, your atrial barrel receptors are sending a signal to your insular cortex and your
insular cortex is saying, wow, I'm really stressed out.
My blood pressure is up.
You don't actually have to measure your blood pressure with a cuff.
Your insula is doing it for you.
It's not getting a quantitative readout, but it's getting a qualitative readout.
The main effect of inhibiting or reducing the activity of the insula was that the intensity of an outside world experience led to a range of different
internal effects. In other words, for most people, a mild shock would induce a mild increase
in heart rate, a mild increase in blood pressure, whereas an intense shock to the skin would
lead to a big increase in heart rate and a big increase in blood pressure.
Turns out the insula is important for establishing that match of intensity.
When the insula is inhibited, what ends up happening is that a mild shock can create a big
increase in blood pressure, and that can be maintained such that anything that's paired with that shock like a bell or a tone would lead to a big increase in blood pressure. You've probably
seen examples of this in the real world, maybe this is even you. Some people are very jumpy in response
to just even small changes in their environment. So if somebody's working and you walk in and you say,
hello, and they'll go, and they're kind of, of they're jumpy They have a low threshold to a big anxiety or a fear response
Other people are really calm. I recall my my bulldog unfortunately passed away
But before he passed away if you walked in the room and you said
Hey, Costello, he might
Turn his eyes in your direction. He had a very high threshold to respond
He was pretty low anxiety animal. A lot of people are like that.
You come up behind someone you say, hello, and they just turn around real slow, or they might just turn around at normal speeds
and say, hello, whereas other people would jump out of their seat. The insula seems to be involved in calibrating how big or high,
how high amplitude a given physiological response is.
So it's pairing the internal landscape with the external world.
And this might seem like just a mechanistic but non-actionable point.
But what you'll see from the next study that I'm going to describe is that recalibrating
the relationship between outside events and internal responses, which is the job of the insula,
is actually something that's under our control.
And through a very simple, very short protocol, we can actually recalibrate that system so
much so that we can potentially reduce the amount of fear and trauma that we experience
in response to a memory or to a real event.
And the entire process can occur very quickly.
So I'm really excited to tell you about this next study for a number of reasons.
First of all, it's extremely recent.
Second of all, it's very well grounded in our current understanding of the mechanisms
of stress trauma and PTSD and unlearning of stress trauma and PTSD. And third, it points to a actionable protocol
that while certainly is not the only approach
that I think people could or should take
for fear trauma and PTSD,
is one that I think we are going to see implemented
into the clinical setting very soon
if it's not happening already.
Now, there's a fourth reason I'm very interested in it,
which is that my lab works on stress, stress relief,
and tools for managing sleep and improving focus, et cetera.
And one of the hallmarks of the studies we've been doing lately
is very brief five-minute-a-day interventions
of the sort that was used in this
particular study, although I should emphasize I had nothing to do with this
particular study. Now this particular study was carried out in an animal model,
in mice, the work in my laboratory focuses on human subjects, but the similarities
of the stress system, at least at the level that it was explored in this study, I
think, have great relevance, maybe even direct relevance to humans.
So the title of this study is repeated exposure
with short-term behavioral stress resolves pre-existing stress-induced
depressive-like behavior in mice.
Again, this study was in mice.
And basically what they did is they stressed out mice,
got them depressed, and you actually can do that in a mouse,
using a restraint protocol,
and that's a long lasting restraint protocol
of 15 minutes or more.
Mice don't like it, you do it often enough,
they stop working so hard in their life,
in their mouse life, to gain food, to gain mates.
They show depressive symptoms and a number of levels,
they show elevated glucocorticoids, You see the same thing in humans, okay?
Chronic stress in humans. Lasting, you know, weeks or more does the same exact
thing. So again, a very close match here in terms of mechanism overall. And then
what they did was a very counterintuitive thing, rather than give these
animals stress relief at the level of reducing their anxiety
with benzodiazepines or giving them
nice little mouse vacation or enhanced
or enriched environment, things that have been done
in a lot of previous studies.
What they did is they subjected them
to five minutes a day of intense stress,
but only five minutes a day.
And what they found was miraculously,
but also very convincingly, daily, short bouts
of intense stress actually undid reversed
the effects of chronic stress.
And it did this at the level of glucocorticoids,
of hormones, of neurotransmitters,
and a number of other different mechanisms.
Now, I find this very exciting for a number of reasons,
but in particular because my laboratory
in collaboration with David Spegel's laboratory
are Associate Chair of Psychiatry at Stanford,
been exploring how five-minute-a-day
respiration protocols can alleviate stress.
And while those data are not yet published,
they are at the stage where I'm comfortable talking about them.
And we are seeing some very impressive and significant effects on stress reduction, not just
from respiration protocols that allow people to calm themselves, but also respiration protocols
that bring people into a heightened state of autonomic sympathetic arousal, aka stress.
As my colleague, Dr. David Spiegel, he's an MD, psychiatrist, and PhD, likes to say, when
it comes to trauma, anxiety, and PTSD, and the treatment of trauma, anxiety, and PTSD,
it's not just the state that you are in or that you go into, it's how you got there,
and whether or not you had anything to do with it.
And this brings us right back to those top-down mechanisms and the narrative around what
we are experiencing internally.
So let's zoom out and I'll explain how this works and what to do about it.
We have this brain structure called the insula.
We talked about the insula a few minutes ago.
The insula is calibrating how we feel internally versus what's going on externally? It's involved in setting whether or not what we are feeling is appropriate given what's happening.
We have a system that can generate threat responses and in the case of trauma PTSD and extreme stress,
conic stress, that system gets ramped up so that it takes very little, maybe even just a memory or maybe even a
gets ramped up so that it takes very little, maybe even just a memory or maybe even an association that we're not even aware of, you know, a location, triggers something, we're
not even aware of it.
And we start experiencing that symptomology.
How do we recalibrate the system?
Well, most of the approaches that are out there involving drug treatments, typical drug
treatments, would involve suppressing the level of internal arousal, just trying to bring
that down. Now, some of those drugousal, just trying to bring that down.
Now, some of those drug treatments work,
but oftentimes they don't.
And if you think about it,
it's probably not surprising that they don't,
because by taking a drug that just lowers your anxiety,
overall, you're creating a different sort
of miscalibration of the system.
So what we've been doing in human subjects is having them do either breathing protocols
that calm them, and I'll explain what that is in a moment, or doing breathing protocols
that increase their level of autonomic arousal and seeing how that impacts their response to stress overall,
not just during that particular breathing protocol.
So the calming protocol that we use involves these physiological size.
I've talked about these previously on the podcast and elsewhere, but if you just need a
reminder, if you haven't heard about it, there's a pattern of breathing that we all do in sleep
when our carbon dioxide levels in our bloodstream get too high and we do this when we get claustrophobic,
meaning we do it reflexively, and that's a double inhale through the nose, followed
by a long exhale.
So it's, and yes, the inhale should be through the nose and yes, the exhale should be done through the mouth ideally.
So it's a big filling of the lungs through two breaths back to back in, inhales.
Even if you can only sneak in a little air on that second one, no talking if you're going to do it right and then a long exhale,
which allows you to offload a lot of carbon dioxide in the exhale.
And we have people doing that in real time,
anytime they experience stress,
but the particular breathing protocol
that we've been giving human subjects
is for them to do the repeated, what we call cyclic sighing.
So double inhale, exhale, double inhale,
exhale, double inhale, exhale, repeatedly for five minutes.
Which is actually a pretty long time to repeat that,
but you can do it pretty slowly.
And people report and the data point to the fact
that it's very calming.
People feel more relaxed afterwards
and that relaxation wicks out into other aspects of their life.
Now, we did not look at stress and trauma in that condition.
We also have another condition where people do what's called
cyclic hyperventilation, which is very different and creates a very different internal state
and is somewhat stressful. It's five minutes a day of stress, much like the study that I
just just described. And it involves basically doing this, what I'll do in a moment for five minutes, which is hyperventilating, which is not continuously for the
five minutes because many people would pass out or feel extremely uncomfortable.
It involves inhale, exhale, inhale, exhale very deep, inhale through the nose, exhale
through the mouth, and then every 25 or 30 breaths or so doing a full exhale and holding one's breath lungs empty for about 25,
maybe 30, maybe even 60 seconds
and then continuing until five minutes is up.
Subjects report and our data indicate
that people feel a heightened level
of autonomic arousal.
In fact, I can feel it right now,
even from that very brief cyclic hyperventilation
about I just did, you
feel a heating up, you feel a, some people will perspire, some people will get wide eyed,
some people feel agitated, that's adrenaline being released into your system.
Now, I'm not suggesting everyone run out and do this, and if you have a predisposition
to panic attack or anxiety attacks, please don't do this because it is very stimulating
and can trigger those sorts of attacks. But this five minute a day protocol of cyclic hyperventilation does lead to big increases
in autonomic ralsals.
So it's stressful in air quotes, but to bring us back to the my colleague, David Speagles
quote, it really was him that said it, not me.
It's not just about the state that you're in.
It's about the state that you're in plus how you got there and whether or not you directed entry into that state.
And that point of that one directs their own entry into a state deliberately is really key.
And I think it has an important implications for whether or not their stress relief and
fear relief and trauma relief from bringing oneself
into a state of increased autonomic arousal.
Why?
Because of the way that that fear and trauma circuitry is organized, if you recall, it's
got these components of how external events can trigger an internal stress response and
fear response and trauma response, but there's that top down prefrontal component that can inhibit certain aspects of that fear
and threat circuitry.
Now earlier we were talking about that prefrontal circuit being engaged through narrative, through
self-directed deliberate narrative.
It's the person deliberately retelling the story.
Here we're talking about a deliberate reactivation
of the sensations in the body. So where I think this is all going, meaning where my laboratory
and the speakable laboratory and other laboratories out there are taking this is you can imagine
a very brief five minutes a day, two weeks was the time that they did this for five minutes
a day for two weeks intervention
in which people with the support of a clinician, we would hope, would deliberately induce a
physiological state that's very stressful, right?
Not shying away from the stress response, but increasing their own stress response deliberately
and maybe in conjunction with recounting the traumatic or fearful circumstance.
This is far and away different than the kind of state of mind and body that would come
about in a ketamine assisted trauma induced psychotherapy session or a MDMA assisted trauma
psychotherapy session or in a purely narrative based psychotherapy session aimed at alleviating
fear or trauma.
The reason I like these sorts of interventions is that A, they are very low cost or even
zero cost, right?
One could, you could imagine doing this while journaling or while recounting a particular
experience.
Again, they're very compact.
Five minutes a day for two weeks is what was done in this particular mouse study.
We don't know if that translates directly to the human study or not.
What was interesting is that if they used longer daily bouts of stress, like 15 minutes
a day, that actually exacerbated the trauma and exacerbated the fear.
So one has to be very careful, stress and deliberate entry into stress
and self-stressing are very potent tools.
They're very sharp blades that it does appear
or it's likely can help alleviate trauma and fear.
But how long to do this, exactly what the protocol should be
is still something that needs to be cultivated.
I know there are gonna be people out there
that nonetheless are going to want to experiment with some of this. I will say that I do not think it matters how one
gets into that stressed state provided it is self-directed and that therefore could be cold shower. It
could be ice bath. It could be anything that induces an acute, meaning
a sudden onset of adrenaline and is self-directed. That's really the key feature here. So I'm
very excited about these data, both the five minute intervention data from the animal
study, the work that's ongoing in my laboratory and Dr. Spegels' laboratory, and the work
that's being done on the insula. Because I think what we're starting to see now is a picture of fear and trauma and PTSD that has this sensory component, what's
happening in the world around us, this internal and teraceptive component, you know, how
appropriate are the signals that are occurring in my body.
I mean, let's face it, if you almost get by a car and your heart rate is, you know, 140
beats per second, and that lasts for a little while and you're stressed out and you don't get the best night's
sleep.
That's pretty normal.
That means you have a healthy fear system.
If that persists and you're dealing with a lot of issues a week later, six weeks later,
two years later, then it's moved into the realm of trauma and PTSD.
So we need to always be taking into account the different components of the circuitry.
I do think that deliberate self-directed entry into the short bouts of stress is a very promising
approach. And it's one that if people are going to experiment, I just again want to caution people
with anxiety or panic disorders, be very cautious, probably don't do it. Ideally, you would do this
in conjunction with support from a clinician. But I'm also aware that there are a lot of people out there that are dealing with trauma and dealing with post-traumatic stress of various kinds,
and that they're desperate for various self-directed intervention approaches. So just very briefly,
I want to touch on some of the lifestyle and supplementation factors that can impact things
like fear and trauma and getting over fear and trauma.
To make a long story short, there are many things that we all can and should do to support
our overall mental and physical health.
These are the foundational elements of quality nutrition, what that means to you.
Quality sleep on a regular basis.
Ample sleep on a regular basis.
We have an episode on how to master sleep.
In fact, we have four episodes that you can go to HubermanLab.com or elsewhere and scroll
down and you can find those episodes in order to get your sleep really dialed in as they
say.
If you're sleeping regularly and for sufficient duration, all of the systems of your
fear circuitry are going to function better, mainly because
the autonomic nervous system becomes very dysregulated when we are not getting good sleep
on a regular basis.
Disregulated means that out of nowhere we can have a higher propensity to have sympathetic
activation or we can feel really tired and wired.
That seesaw that I described earlier of alertness and calmness of sympathetic and parasympathetic.
In that analogy, we can imagine that seesaw has a hinge and that hinge can either be too
tight nor too loose.
If it's too tight, you can get locked into chronic activation of alertness or chronic fatigue.
If it's too loose, you're bouncing all over the place and you might be tired and wired one moment and then really hyper alert, sleep resets that balance
and resets that hinge to the appropriate tightness, if you will, so that all these circuits
and not just the circuits related to fear, but also the circuits related to cognition, clear thinking,
to be able to spell out very clear detailed narratives to feel like you are in control
You are deliberately bringing yourself into these protocols if that's what you intend to use all of that functions must much better when you're sleeping well and eating well
We talked about social connection. Those are all indirect supports of
Trauma relief and of getting over fear, but they are essential. Okay, I think of them sort of like the tide
when the tide is high enough a boat can leave harbor and if the tide is not high enough
then that boat is going to be stranded on shore and in this analogy the boat stranded on shore is your attempt or
anybody's attempt to try and work through something very hard to do when we're sleep deprived very hard to do when we're not
fed enough or fed the proper foods work through something very hard to do when we're sleep deprived, very hard to do when we're not
fed enough or fed the proper foods for you. And that's a highly individual thing. And social connection, as we talked about earlier, creates a general sense of support for the ability to move
through things, but also chemical support at the level of suppressing tacky kind in. Okay, so
those foundational elements are absolutely key, but they are indirect. I just want to briefly mention a few of the things that some people find great benefit from
in the supplementation realm as it relates to anxiety, stress, fear, and PTSD.
But I want to point out that again, these are somewhat indirect in their support and most
of them focus on reducing anxiety overall.
The two that I want to focus on are two that I've never talked about on this podcast before
because I've done podcasts before on stress and managing stress in the kind of shorter
term.
So we've talked about Ashwagandha in a previous podcast.
Check out the podcast on stress if you're interested in how that might be relevant as well as
other tools.
But the two are interesting ones.
The first one is saffron of all things, but there are 12 studies, believe it or not, that
early ingested saffron at 30 milligrams seems to be a reliable dose for reducing anxiety
on the standard inventories, the Hamilton and the anxiety rating scale for
those of you that want to know.
And these are significant effects and these were carried out in both male and female subjects.
Here I'm only referring to human studies.
Several of these were double blind studies.
There's a meta-analysis of the positive effects, meaning anxiety, leotic effects, anxiety
reducing effects that is of things like
saffron. Definitely have to check with your doctor, make sure it's right for you, but
they're fairly impressive effects when you really think about it, given that these are
legal over the counter substances. Again, check with a doctor. The other one is
anositol. Anositol has been shown to create a very notable decrease in anxiety symptoms.
It's a fairly high dose that's used, but believe it or not, the potency of this effect
is on par with many of the prescription antidepressants.
That's pretty impressive.
These studies again are double blind studies that all showed decreases in anxiety.
These were done in males and females.
The age range is very broad, which is great.
18 all the way up to 64 across the studies that I looked at.
One of the more important things is that the dosages are quite high.
18 grams of anositol taken for a full month.
And it does take some time for these symptoms of anxiety to be improved.
The low dose range was about 12 grams of inocitol,
so as high as 18, as low as 12 grams.
But then again, pretty impressive results
considering that these are over the counter supplement
compounds.
There's even some evidence, I should just mention
that the inocitol is also used for things
like obsessive compulsive disorder.
We will do a full episode on OCD in the future, you can count on that.
But in the meantime, anositol does seem to have some positive effects on anxiety.
And therefore, it might provide a kind of supportive indirect effect for people that are trying
to work through trauma and PTSD.
Now the question is, when would you take it?
Well, by the logic of what we spelled out today,
you probably would not want to take it during a session
or prior to a session where you were trying to amplify
the intensity of an experience
and the recounting of an experience
in efforts to eventually extinguish that experience, right?
Because if you put a drug or a compound of any kind,
prescription drug or supplement or any of any kind,
into your system, you are essentially short circuiting
the extinguishing effect, right?
So you can imagine doing this outside of that session
as a way to kind of bring your system back to baseline, perhaps.
So if you're going to use these sorts of things,
you want to think about them logically.
And this also really points to the fact that many of the things that people are doing
out there to self-medicate over use of alcohol or other substances to try and calm themselves
because they have fear anxiety and PTSD are actually driving that fear anxiety and PTSD
deeper into their system, or at least is not allowing it to relieve itself through any
attempts to recount or replay and using these top down narrative circuits or other approaches.
And the last compound I want to mention is a particularly interesting one because it's
neither an anxioleotic nor is it something that increases overall levels of stress and
alertness.
But it has some kind of MDMA-ish-like contour to it.
It does not produce as far as we know, the same mental effects or physical effects as
MDMA by any stretch.
But that's the substance that I'm referring to rather is Kava.
Kava has been shown in eight studies to have a very potent effect on reducing anxiety. But what's interesting about
Kava is that Kava functions by increasing GABA, this inhibitory neurotransmitter in the brain.
Remember GABA is the inhibitory neurotransmitter that is used, that's employed by the very neurons
in the prefrontal cortex that serve to inhibit the threat reflex. So it seems to increase GABA, but it also increases dopamine.
And that's a somewhat unusual compound.
I'm not aware of many compounds that simultaneously
increase GABA and increase dopamine.
And as you recall, that threat reflex
has outputs that tap into the dopamine system.
Now, that's a big leap to go from a compound that
increases GABA and dopamine and look at a circuit spelled out on paper in front of us and say, oh, that's a big leap to go from a compound that increases GABA and dopamine and look at a circuit spelled out on paper
in front of us and say, oh, well, there's GABA and dopamine
in this circuit and therefore this is a good compound to take.
But the effects of GABA and human studies are pretty interesting
as it relates to anxiety, stress, PTSD, and fear.
I'm not going to summarize all of these because there are eight studies that I'm aware of,
but I'll just mention again, these are double blind studies, so the trial design is solid. The
age ranges are anywhere from 18 to 64, which is a nice broad age range. The number of subjects is
quite high. Both men and women, no signs of hep- hep- hep- a toxic signal, so meaning liver toxicity,
although of course, check with your doctor.
But what was interesting is that after a period of about three weeks of treatment, with anywhere
from 150 milligrams of what are called active cova lactones, okay, so there are dosages
that relate to that cova, so 100 milligrams of extract of cova is a kind of a reasonable typical dose in these studies, but that spells out to a certain amount of cova lactone, so you have to kind of boil down to what is the appropriate dosage, and it turns out it's kind of all over the place. But each of these studies alone and together point to the fact that Kava does seem to produce
a very potent, angiallotic and general kind of improvement in depressive symptoms and
reduction in generalized anxiety across the board.
So it's an interesting compound.
I've never actually tried any of the compounds I just mentioned.
Kava, saffron, or Anisatal. So I can't report on them personally. I just know that a number
of listeners of this podcast are interested in supplements and legal over-the-counter approaches
to their biology and psychology. And so that's why I mentioned them. Those were the three
for which I found the most convincing evidence and the largest bulk of evidence.
So if you're interested in exploring those,
proceed with caution, but they do seem quite interesting.
So today we've reviewed a large amount of information
about the biology of pathways in the brain and body
that underlie the fear response
and they give rise to chronic fear
and in some cases to trauma and PTSD.
We also touched on a large variety of approaches to dealing with fear, trauma and PTSD that
currently exist in the clinical landscape out there.
I also touched on some of the emerging themes.
For instance, this short five-minute-a-day deliberate self-directed stress of any kind through respiration or other
approaches of increasing adrenaline as an approach that might be viable and should
emphasize might be viable for enhancing the speed or the potency of treatments to reduce
fear or eliminate trauma.
Most important, I believe, is to understand and really think about
the logical structure of the circuits that underlie fear and PTSD. Because in doing that,
each of us, all of us, can think about what sorts of treatments and approaches make the
most sense for them. I also hope that it will help people lean into certain practices involving
re-exposure, provided that's done in a supportive environment, re-exposure provided that's done in a
supportive environment, re-exposure to a given traumatic event in an attempt to
extinguish that. Obviously you want to do that safely, meaning psychologically
safely and physically safely. There are great practitioners out there that can
help you with that work. There are also a number of people out there I am certain
that are carrying certain traumas or certain fears that they would like to alleviate
that are not in the extreme clinical realm.
That's the reason why I touched on a number of things, including some self-directed practices
that might be useful and reasonable for them to explore.
I realize we covered a lot of information today.
If you're enjoying and are learning from this podcast and you're not traumatized by the
amount of information covered, please're enjoying and or learning from this podcast and you're not traumatized by the amount of information covered please subscribe
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