Huberman Lab - Dr. Casey Halpern: Biology & Treatments for Compulsive Behaviors & Binge Eating
Episode Date: September 26, 2022My guest is Casey Halpern, M.D., Chief of Stereotactic and Functional Neurosurgery and Professor of Neurosurgery at the Perelman School of Medicine at the University of Pennsylvania. Dr. Halpern’s r...esearch and clinical practice focus on using deep brain stimulation to treat compulsive and movement disorders (e.g., binge eating disorders, bulimia, obsessive-compulsive disorder (OCD) and Parkinson’s disease essential tremor, dystonia). We discuss using deep brain stimulation to help patients who suffer from movement and compulsive disorders and applying this treatment to patients afflicted with binge eating. We also explore applications of this technology to other conditions such as OCD, anorexia and tremor, and the future therapeutic directions of the use of non-invasive brain stimulation approaches, including transcranial magnetic stimulation and ultrasound, for the treatment of other psychiatric illnesses and conditions. This episode will interest those curious about the biology of eating, anorexia, bulimia, compulsive thoughts and behaviors, and movement. 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) Dr. Casey Halpern & Disordered Eating & Brain Stimulation (00:03:35) Sponsor: LMNT (00:08:28) Neurosurgeon’s View of the Brain, Neurosurgery Specialization (00:13:05) Deep Brain Stimulation & Other Unexpected Positive Effects (00:17:20) Obsessive Compulsive Disorder (OCD), Prescriptions & Cognitive Therapies (00:25:40) Brain Areas in OCD, Risk, Rewards & Addiction (00:29:30) Sponsor: AG1 (00:32:27) Facial and Vocal Ticks, Stimulants, Stress & Superstition (00:39:28) Nucleus Accumbens, Reward Circuits, Eating Disorders & Obesity (00:47:18) Stimulation of Nucleus Accumbens, Continuous vs. Episodic Stimulation (00:49:49) Binge Eating Disorder & Loss of Control Eating (00:53:02) Developing Binge Eating Disorder: Predisposition, Environment, Stress (01:02:07) Electrodes in Nucleus Accumbens, Identifying “Craving Cells” (01:11:41) Effects of Stimulation, Interrupting Craving, Intermediate Stimulation (01:16:46) Anorexia, Obesity & Compulsions, Potential Treatments for Anorexia (01:23:14) Non-Invasive Brain Stimulation, Transcranial Magnetic Stimulation (01:32:27) MRI-Guided Focused Ultrasound: Tremor, Essential Tremor & Parkinson’s (01:36:40) Future of Non-Invasive Brain Stimulation, Epilepsy & Depression (01:41:51) Pre-Behavioral States in Compulsion & Awareness, Mood Provocation (01:48:02) Machine Learning/Artificial Intelligence & Compulsion Predictions (01:53:05) Neurosurgeon Hands, Resistance Training & Deadlifts (01:59:00) “Neurosurgeon Calm,” Quality Time & Prioritization, Neurosurgeon Training (02:09:53) Daily Habits: Sleep, Exercise, Mediation (02:11:59) Zero-Cost Support, YouTube Feedback, Spotify & Apple Reviews, Sponsors, Momentous Supplements, Neural Network Newsletter, Instagram, Twitter, Facebook, LinkedIn Title Card Photo Credit: Mike Blabac Disclaimer
Transcript
Discussion (0)
Welcome to the Uberman Lab podcast where we discuss science and science-based tools for everyday life.
I'm Andrew Uberman and I'm a professor of neurobiology and
Ophthalmology at Stanford School of Medicine. Today my guest is Dr. Casey Halpern.
Dr. Halpern is the chief of neurosurgery at the University of Pennsylvania School of Medicine.
His laboratory focuses on bulimia,
University of Pennsylvania School of Medicine. His laboratory focuses on bulimia, binge eating disorder,
and other forms of obsessive compulsive behaviors.
Normally, when we hear about eating disorders
or obsessive compulsive disorders of other kinds,
the conversation quickly migrates
to pharmacologic interventions and serotonin or dopamine
or talk therapy interventions,
many of which can be effective.
The Halpern laboratory, however,
takes an entirely different approach. While they embrace pharmacologic and behavioral
and talk therapy interventions, their main focus is the development and application of engineer
devices to go directly into the brain and stimulate the neurons, the nerve cells, that generate
compulsions, that cause people to want to eat more even when their stomach is full.
In other words, they do brain surgery of various kinds, sometimes removing small bits of
brain, sometimes stimulating small bits of brain with electrical current, and even
stimulating the brain through the intact skull.
That is, without having to drill down beneath the skull in order to alleviate and indeed
sometimes cure these conditions.
Today's discussion with Dr. Halperin was an absolutely fascinating one for me,
because it represents the leading edge
of what's happening in modification of brain circuits
and the treatment of neurologic and psychiatric disease.
For instance, they just recently published a paper
in Nature Medicine, one of the premier journals out there,
entitled Pilot Study of Responsive Nucleus Accommods,
Deep Brain Stimulation for for loss of control eating.
The nucleus accumbens is an area of our brains that we all have, in fact we have two of them,
one on each side of the brain, that is intimately involved in the release of dopamine for
particular motivated behaviors. And while most often we think about dopamine for the release of
behaviors that we want to engage in, in this context, they are using stimulation and control of neuronal
activity in nucleus accumbens to control loss of control eating. Something that when people
suffer from it, despite knowing they shouldn't eat, despite not even wanting to eat, they
find themselves eating. So again, this represents really the leading edge of where neuroscience
is going, and certainly is going to be an area of neuroscience that's going to expand
in the years to come. And Dr. Halpern and the members of his laboratory are among a very small group of scientists in the
world that are using the types of approaches that I described a minute ago and that you're going
to hear more about in today's episode in order to resolve some of the most difficult and debilitating
human conditions. During today's discussion you will also learn about the use of deep brain stimulation
and other approaches for the treatment of movement disorders, such as essential tremor, Parkinson's disease,
and various types of dystonias, which are challenges in generating particular types of movement.
So whether or not you or somebody that you know suffers from an eating disorder, from obsessive
compulsive disorder, or from a movement disorder, today's episode is sure to teach you not only
about what's happening in those arenas, but also in the arenas of neuroscience generally. In fact, I would
say today's episode is especially important for anyone that wants to understand how the
brain works and what the future of brain modification really looks like for all of us.
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. Our first sponsor is Element. Element is an
electrolyte drink with everything you need and nothing you don't. That means plenty of salt,
magnesium, and potassium, the so-called electrolytes, and no sugar.
Salt, magnesium, and potassium are critical to the function of all the cells in your body
in particular to the function of your nerve cells, also called neurons.
In fact, in order for your neurons to function properly, all three electrolytes need to be
present in the proper ratios.
We now know that even slight reductions in electrolyte concentrations or dehydration
of the body can lead to deficits in cognitive and physical performance.
Element contains a science-backed electrolyte ratio of 1000 milligrams, that's 1 gram of
sodium, 200 milligrams of potassium, and 60 milligrams of magnesium.
I typically drink element first thing in the morning when I wake up in order to hydrate
my body and make sure I have enough electrolytes. And while I do any kind of physical training and
after physical training as well, especially if I've been sweating a lot, if you'd like to try
element, you can go to drink element that's LMNT.com slash Huberman to claim a free element sample
pack with your purchase. Again, that's drink element LMNTment.com slash Hubertman. And now for my discussion with Dr. Kasey Halpern.
Kasey, I should say Dr. Halpern, those listening. Welcome.
Thank you. Great to be here. Yeah. It's been a long time coming.
We were colleagues at Stanford. And then recently, you moved, of course,
to University of Pennsylvania, also an incredible institution.
We're sorry to lose you. So... It's been a sweet for me, too.
Stanford's loss is you pens gain, but let's talk about your work past and present.
As I've told the listeners already, you're a neurosurgeon, which I consider the astronauts
of neuroscience, because you're in somewhat uncharted territory, or very uncharted territory, and yet precision is everything,
the margins of error are very, very small.
So for those that aren't familiar
with the differences between neurosurgery, neurology,
psychiatry, you just educate us a bit.
What does a neurosurgeon do,
and what does the fact that you're a neurosurgeon
do for your view of the brain? How do you think about and conceptualize the fact that you're a neurosurgeon do
for your view of the brain?
How do you think about and conceptualize the brain?
Yeah, the scope of neurosurgery is quite broad.
When I was in medical school,
I was drawn to neurosurgery
because of a procedure known as deep brain stimulation.
When I was at Penn as a college student,
I actually watched my first deep brain stimulation surgery
performed by Gordon Balthuk, who to date is one of my career mentors.
Deep brain stimulation is one surgery that neurosurgeons offer, but it's actually sort of a
very small minority of what neurosurgery does.
We take out brain tumors, we clip aneurysms in the brain.
We take care of patients that have had traumatic brain injury, concussion, spine surgeries,
90% of what neurosurgeons do around the country, taking care of herniated discs and lumbar
fusions.
So, the scope is the entire central nervous system, including the peripheral nervous system,
we take care of patients with carpal tunnel syndrome and nerve disorders.
Now of the course of the past two decades or so, there's been a mission in the field
to subspecialize.
And so historically, neurosurgeons did everything in that domain. But now we subspecialize, and I'm lucky to be at Penn Medicine
where we can focus on one of these areas.
So I'm a chief of stair-tacking functional neurosurgery.
All I do is deep brain stimulation surgery
and a complement to that is focus ultrasound
or trans cranial focus ultrasound, which
is a non-invasive way
to do an ablation in the brain. Recently FDA approved and it's FDA approved for trebr
at the moment. These two procedures are for me, my every day, but still the minority of what
neurosurgeons have to offer. The majority of neurosurgery in my mind is a bit more structural than it is
physiology or deeply rooted in how the brain functions. When we take out a brain tumor, we have to find
a safe trajectory to get to the brain tumor and then we remove it and we help the patient recover
in the ICU. Similar to a brain aneurysm, often we don't have to go into the brain to clip a brain aneurysm,
but we go around the brain or under the brain to get there.
And in my mind, those surgeries are a bit more structural.
Deep brain stimulation, the surgery that I do routinely, is a procedure where, yes,
there is structure involved, of course. We have to place a very thin wire that's insulated deep into a part of the brain that's
involved in Parkinson's disease, for example.
But that's actually not the therapy.
The therapy is delivering electrical stimulation through the tip of that wire, or one of the
tips, as there actually are multiple contexts
at the bottom of the wire.
They're very small.
But that's all done out of the operating room.
This stimulation wire is connected to a battery pack
or a pulse generator that's kind of like a pacemaker.
And so we deliver this therapy, and I always tell patients,
it's a bit more like I have to implant a tool to deliver you a
medication, but that medication is going to be in the form of electricity and
it's going to be delivered into a very small region of the brain. And it's that
procedure that inspired me to not just become a neurosurgeon but has really
defined the focus of my research laboratory as well. Maybe by wave, antitut, you could tell us one of the more outrageous or surprising or
who knows delightful and thrilling things about the brain that you've observed as a consequence
of stimulating different brain areas.
You know, in textbooks, we always hear about the kind of dark stuff. Stimulate one brain
area, somebody goes into a rage, stimulate another brain area, person starts laughing uncontrollably.
First of all, given that some of the information, let's hope not much, but some of the information
textbooks is incorrect, are those sorts of statements true? Can one observe those in the
clinic? And what are some of the more interesting,
and I don't necessarily mean entertaining,
but surprising things that you've seen
when you've poked around in the brain deliberately,
of course, and what have you seen?
What have you heard?
I have to say, I am amazed by these effects every day.
I'm very privileged to be able to interact
with the human brain in this way.
It's always in them with the goal of trying to provide
somebody with a meaningful therapy.
But when we deliver electrical stimulation,
these electrodes, while they might be sitting
in a very small region of the brain,
there are regions within a few millimeters
of where these electrodes are
that if stimulated could cause a temporary,
very brief side effect, a moment of laughter, like you said, or a moment of panic. And of
course, we can just shut that electrode off. But often, these side effects could be therapeutic.
And actually, that's how we have discovered ways to use deep brain stimulation, not just
from movement disorders, like Parkinson's disease, but for example patients with Parkinson's disease that have a psychiatric comorbidity like depression or obsessive compulsive disorder.
A lot of these patients are highly compulsive and impulsive.
Sometimes these problems actually melt away and we're trying to help their tremor, but the
patients also tell us that their gambling
issue has gotten better, or their mood has improved.
And why is that?
Well, you know, there's probably more than one reason, you know, you can help somebody's
mood by making their tremor go away, of course.
But we see laughter in the clinic sometimes.
And why is that?
And that's because we're stimulating parts of the brain that are not just involved in
these motor circuits, but they're also involved in what we call a limbic circuit or part of the brain involved
in emotion.
And if we learn how to modulate those areas therapeutically, step by step, we can actually
develop these therapies for other indications like depression.
I would say the most impressive and consistent effect we have, and we have a patient with
tremor, who has been tremoring for the past 20 years.
If we can deliver stimulation through that electrode
in the clinic, we have a immediate relief of tremor.
And that is the effect that inspired me to be a neurosurgeon
when I was in college.
I've never really wanted to do anything else,
except help develop that type of therapeutic
for another kind of symptom.
I'm very interested in obesity and related eating disorders,
compulsive behavior that urge to have something that might be delicious,
but dangerous or unhealthy or a drug or a compulsion like we see in OCD,
or a test of compulsive disorder.
Interestingly, like we see tremor melt away
when we deliver electricity to a certain part of the brain,
we can see these psychiatric, more psychiatric problems.
They're not all psychiatric disorders,
but let's say disorders of the brain,
we can see symptoms of those disorders also improve,
and often immediately, just like we do with tremor. So I see it all the time to pick out one would be a challenge,
because for me, this is my eye every day.
The speed of the relief that you describe for tremor is really incredible. Just thinking
about drug therapies and there are two, there their side effects, but there are still a lot of mysteries as to, for instance, why SSRIs even work when they work.
And the timing is always a challenge.
Timing dosage, yes, absolutely.
I'd love to learn more from you about OCD.
I have several reasons for asking this.
First of all, I'm a somewhat
obsessive person. I tend to be very, very narrowly focused, although I confess it's not
a step function. It takes me some time to turn off the chatter, but once I'm into a thought
train or a mode of being and thinking and work, it's very hard for me to exit that mode.
It's like a deep trench. Adaptive in some circumstances less adaptive.
In others, you know, the other is that when I was a kid, I had a little bit of a grunting
tick. I used to, I had a, this intense, intense desire to clear my throat to the point where
my, my dad said, look, you need to stop that. He used to squeeze my hand every time I do
it. And I used to hide in the back seat of the car or in the closet to do it because it provided so much relief.
And then it eventually passed.
I wasn't medicated.
They never did anything about it.
Every once in a while now, if I'm very fatigued,
if I've been working a lot, I notice it starts to come back.
I'll do this kind of grunting.
And so it's been a pet neurologic symptom for me that reminds me that these circuits exist in all of us.
And that sometimes they go, hey, wire and sometimes they just have subtle, you know, over excitation or something of that sort.
And then the third reason is that I get thousands of questions about OCD.
Could you perhaps just tell us what is OCD?
Sure.
What are some brain areas involved?
What are the current range of treatments?
And what's the difference between someone who is obsessive
and somebody who has true OCD?
So a brief disclosure, as a neurosurgeon,
I do take care of patients with severe obsessive compulsive
disorder.
But my perspective on OCD may be a little bit different
than a psychiatrist who lives and breathes OCD
and sees patients every single day with OCD.
I probably take care of a three to five patients a year
with deep brain stimulation for obsessive compulsive disorder.
So I don't see these patients as routinely,
but my laboratory is geared as a researcher. I'm very focused on trying to improve outcomes of deep brain stimulation
for OCD. So I do feel I have expertise and a perspective to share, but just a brief
disclosure. I do feel that as a neurosurgeon, I am obligated to better understand where the obsessions
and the brain come from and how we can interrupt them to stop the compulsion that's associated
with the obsession, sort of the intrinsic most feature of OCD, better than we're actually
doing it.
For example, if we were to offer a patient with tremor
deep brain stimulation surgery,
of course there's some risk to the procedure,
but the outcome is so consistent and positive
that many patients are willing to take on that risk.
For obsessive compulsive disorder,
the surgery risk is about the same. However, the benefit is not quite as robust.
And so a lot of patients and their referring psychiatrists are reluctant to refer these
patients to us. And it's completely understandable. I've been leading an endeavor with a number
of collaborators around the country to try to better understand these circuits in the brain, study them in humans,
both invasively and non-invasively, that would be with an electrode-based surgery, sort of like
we do in epilepsy to understand where seizures come from, we want to understand better where
obsessions come from, but we're also working with imaging experts and geneticists to understand OCD at a broader level as well.
I consider OCD to be a spectrum disorder in a way.
And I apologize to those who might feel that I'm using that term incorrectly.
I'm using it in a way to describe patients that have obsessions
and even some related compulsions.
It might not be criteria for OCD.
It may be something Andrew that you have.
As a neurosurgeon, I'm really obsessive about safety and compulsive about my surgical procedures.
So I think that some aspect of OCD, which we often joke about, but we should consider seriously,
because people do suffer from this, Some aspect of it helps us.
There are famous CEOs that probably have some level of OCD surgeons and scientists alike.
So, perhaps if it can be controlled, it's an asset.
But if it goes awry and is uncontrollable, then it becomes obsessive compulsive disorder.
And I tend to see the patients that are the most severe.
So they have failed medication, and there are multiple medications that are worth trying
for OCD.
Some can actually be very helpful.
Which neurotransmitter systems do they tend to poke at?
Well, SSRIs are sort of the first line for OCD, but also tricyclics can be helpful.
So this is still the serotonin system.
But as we know, the serotonin system interacts
with the neuro-agenergic system and the dopamine system.
So it's hard to be specific to one of these things.
And I think that's also why it's hard for us
to predict how these medications are going
to work for these kinds of patients.
But tricyclics and SSRIs can be very helpful and are definitely first line.
And there's others.
Exposure response prevention is probably the most effective option, which is kind of like
cognitive behavioral therapy, but these are different and offered by psychologists.
And this is a whole field. And there's a field, I should say, a whole clinic
at my institution focused, started by Edna Foa at Penn,
who this is what they do for these patients.
It is offered these types of cognitive therapies,
exposure to the stressor, and to try to get patients to habituate to
whatever it is that stresses them and causes these compulsions to help these patients live
in every day and function. These are all fabulously helpful therapies for a variety of patients,
but there's still about 30% of patients that still suffer from OCD and some of them have
severe OCD, sometimes it's moderate to severe, and those are the patients that still suffer from OCD and some of them have severe OCD, sometimes
it's moderate to severe, and those are the patients that I'm really motivated to try
to help. Our therapies for those patients right now, I would say, are worth pursuing, but
not optimal. And so it's one of those things that we have to balance as a researcher, because
when you see patients like this, you want to do everything you can to help them. And
I think it's important to educate patients
on the risk and benefits of them.
This is deep brain stimulation surgery,
but also capsillotomy, which is more of an ablation approach.
A little bit like deep brain stimulation,
but rather than delivering stimulation through an electrode,
you can actually heat the tissue and even destroy it.
Some would say this part of the brain is very safe to destroy.
It's kind of like an appendix.
Others would say it's safer to modulate.
I have seen patients do very well with these ablations.
And so, you know, you asked me earlier what I find so amazing
about the brain, these effects that we can have.
Sometimes the lack of effect is what's so amazing.
You can actually traverse parts of the brain without having
any adverse effects on patients,
function at least that you can test. But you can also destroy small parts of the brain.
We're talking three or four millimeters in size. These little ablations can be really helpful for
patients, but have no obvious side effects that we can tell, perhaps after a short recovery from
surgery. But nonetheless, despite how safe they might be, these surgical procedures still are surgical procedures.
And patients are hesitant to proceed,
especially when they know that their chance of a
transformative effect is quite low.
We can generally achieve a responder rate of about 50%.
And responders still have symptomatic OCD.
So I'm really sort of inspired to really find a way
to deliver these therapies in a more disease-specific
or symptom-specific way,
but we're years away probably from that therapy
since it's all part of a research study at the moment.
What brain areas should I think about when I think about OCD?
Years ago, I remember opening a textbook,
I think it was an undergraduate still, and work from Judith Rappaport at the National Institutes
of Mental Health, this would be late 80s or early 90s, had done some neuroimaging, or
maybe it was pet of some other imaging technique, and had identified portions of the basal ganglia, caught, eat, butane, and type structures in OCD,
and maybe some differences in boys versus girls.
So what brain areas are there sex differences in terms of OCD?
And we're one to come into your clinic for this sort of work
of ablations or stimulation.
Where would you first start to probe in the brain?
Yeah, this is a disorder of both cortex and the sub-cortex. The cortical control areas,
areas that are involved in inhibitory control, we have found to not function properly in patients
with OCDs.
So areas like the overall frontal cortex and the prefrontal cortex, if you image these
areas or study them even in a eroded model of OCD, which, quite honestly, these models,
they model aspects of OCD, but OCD is a human condition.
You can't really model this whole condition in a mouse or a wrap, but perhaps
you can model compulsive behavior in a wrap, sure.
And then rolling out their hair.
Yeah, exactly. That's not necessarily obsessive compulsive disorder, but that is compulsive
behavior. And perhaps if you can ameliorate that in a wrap, that might be helpful for
a patient with OCD, but we have to approach animal modeling of OCD thoughtfully. And most scientists do, I think.
When we study OCD in models or in humans with imaging,
and we're trying to do it inbasively with electros
like we do in epilepsy patients,
we find that areas in the cortex
like the prefrontal and over-frontal cortex
are not functioning the way they would in a non-OCD patient.
They are often hyper functioning, such that while you might say, well, they're hyperfunctioning,
so aren't these patients functioning better?
Hyper-focused.
Yeah, hyper-focused, exactly.
No, I would say it's not so much an upper or down, it's more that they're just dysfunctional.
And we need to find a way to try to restore normal function to these areas.
It's not so much directional, really.
We tend to oversimplify brain function
by thinking about it with directionality too much.
Unfortunately, imaging studies sometimes
demonstrate activation or hypoe activation.
And that's where I think these kinds of things
can be misconstrued.
But what I would call the cortical areas of OCDs
that they're dysregulated,
and we need to find a way to try to normalize their function.
So the frontal lobe is huge,
but areas of the frontal lobe that are a bit more basal,
like the OFC or OBITO frontal cortex and the prefrontal cortex,
definitely consistently seem to be
implicated in patients with OCD.
And then their projections to the sub cortex.
This is the basal ganglia, like you were saying,
called a putamen or the dorsal stratum. And these are interconnected with the ventral stratum.
This is an area of the brain that I focus a lot of my energy and this is the ventral stratum,
which is not limited to, but includes the nucleosacumbans. This is an area of the brain that
we know to be involved in gating, reward-seeking behavior behavior when it's perturbed. It seems to gait compulsive behavior, meaning a rat will pursue a reward despite punishment,
despite a foot shock, for example.
And that can be similar to an OCD patient.
They will check their home for safety until 3 a.m. in the morning and not sleep that night.
In a way, that is similar to a rat seeking out a food reward despite a
foot shock, doing something because of the urge but despite the risk. And perhaps
there is some normal judgment there. We all have to take risks to function in
everyday society. To be successful we have to take a risk. To take care of patients with surgery,
there's some risk there.
We make a judgment call, and that's not a condition
that that's just normal.
But when our judgment is consistently sort of puts us
at risk, that's where we have something like OCD.
But OCD is also, you know, it's one of many conditions
that suffer from these kinds of problems.
We tend to label them because they tend to present
in a consistent way.
So we have patients with OCD that have hyperchecking behavior
or contamination behavior where they feel contaminated,
they'll wash their hands for hours repeatedly
or if they drop their toothbrush on the floor,
this will lead to a compulsive behavior of cleaning a toothbrush, brushing your teeth consistently, very, very
common symptoms that we see, or signs that patients report to us, or that we observe.
But patients with eating disorders, they tend to, if they have been gene disorder, they'll
overeat, if they have bulimia, they might purge, despite the risk of these things.
And so addiction is similar.
We tend to drug seek if we're addicted,
we'll pay off a dealer in order to get our effects
and despite the risk.
And that type of urge despite the risk
is something that I've always been really interested in.
And it's a common denominator to all of these problems.
And if you think about these problems, I mean, these are some of the most common conditions
in our society today.
I'd like to take a quick break and acknowledge one of our sponsors, Athletic Greens.
Athletic Greens, now called AG1, is a vitamin mineral probiotic drink that covers all of your
foundational nutritional needs.
I've been taking athletic green since 2012,
so I'm delighted that they're sponsoring the podcast.
The reason I started taking athletic greens
and the reason I still take athletic greens
once or usually twice a day
is that it gets to be in the probiotics that I need
for gut health.
Our gut is very important.
It's populated by gut microbiota
that communicate with the brain, the immune system,
and basically all the biological systems of our body
to strongly impact our immediate and long-term health.
And those probiotics and athletic greens are optimal and vital for microbiotic health.
In addition, athletic greens contains a number of adaptogens, vitamins, and minerals that
make sure that all of my foundational nutritional needs are met.
And it tastes great.
If you'd like to try athletic greens, you can go to atlettagreens.com slash huberman. And they'll give you five free travel packs that make it
really easy to mix up athletic greens while you're on the road and the car on the plane,
et cetera. And they'll give you a year supply of vitamin D3 K2. Again, that's atlettagreens.com
slash huberman to get the five free travel packs and the year supply of vitamin D3 K2.
Yeah, I really appreciate that you're building this bridge for most CD to nucleus accommons, to get the five free travel packs and the year supply of vitamin D3K2.
I really appreciate that you're building this bridge for most CD to nucleus accommons,
which is of course associated with reward in various forms, and we'll get to that.
I'll share a personal anecdote as a form of question.
When I was in college and studying a lot. I relied on caffeine as a stimulant.
I've never really been into drugs or alcohol.
I've been lucky in that sense.
I don't drink and I could care less of alcohol
disappeared.
Never really like recreational drugs.
So it was never drawn to them.
However, when I was in college, at the time,
there were these little epinephrine pills
that were common in a lot of sport supplements.
These are like pre-workout type things.
Not unlike energy drinks now, which I completely avoid.
And I had this experience of taking one of these and drinking some coffee.
And of course, it gave me a lift in energy.
These are very similar to M. Fedemign.
They were legal over the counter at the time.
They're now either banned or illegal.
I do not recommend them.
And I had a lot of energy,
but what I noticed is that my grunting tip came back and I had, I made one mistake. I still think
of this as one mistake, which was I engage in a superstitious behavior. I knocked on wood. And then
somehow it felt very rewarding. Like it gave me some totally irrational, but internally rational sense of security around,
I forget what I was knocking on wood about.
And I found that I couldn't break that knock on wood compulsion.
I felt I needed to knock on wood.
And so then I started sneaking knock on woods
like in mid exam and studying and pretty soon,
I was knocking on wood often.
I developed a superstition.
And so I'm curious about the role of superstition
and compulsion
and the crossover there. It makes sense logically to me, but I was equally shocked to learn that when I
stopped taking this stimulant, which I was quite happy to stop because it did make me feel too
alert, couldn't sleep well, et cetera, that the superstition went away as well. And I'm guessing
this has something to do with some of the reward circuitry,
as it's called, related to stimulants. Again, I am not encouraging anyone to take stimulants,
although healthy use of caffeine or safe use of caffeine might be the one universally accepted
stimulant. It was really surprising to me how quickly this came on, how quickly it engaged my thinking and my behavior, the
obsessions and the compulsions, and how quickly it turned off when I stopped taking this
sports stimulant or whatever it was. I don't even remember. I think it was some form of epinephrine,
a fedron. It's not epinephrine, excuse me, I'm a fedron. This is what I described sound totally outside the bounds of logic or am I imagining
it all? No, it did happen. I'm certain it happened. Yeah, no, I don't think you're imagining
it at all. The grunting that you mentioned to me, first of all, I didn't comment, but
that's sort of, that's put a label on it, but it sounds like a tick. And, you know, ticks in young males extremely common,
and they do tend to go away.
Linking ticks like that.
I just have a good friend who,
yeah, she's a famous neuroscientist,
and I won't mention who it is.
It's worked very hard to suppress his blinking ticks.
And when he gets fatigued, it comes back.
And he's very high functioning
in his personal life and his professional life.
But when you're talking to him and he starts doing this,
so you kind of start wondering what's going on.
Yeah, and it's unfortunate.
People with these problems,
especially as they get more severe
than you get Tourette Syndrome,
it's hard to function in our society.
I have some friends that have Tourette and I'll tell you,
I'm just so inspired because they're so,
they're so confident and people obviously notice these problems, but they just live their life and they're very successful.
And that's not typical.
I have friends that I went to Penn with undergrad that had
these kinds of problems and I was always just so happy and inspired by them.
But what's more typical is these you know, these problems cause people to lose
their confidence and not, you know, pursue, you know, their profession as they may have done or
the things of that nature. So I think it's all related to the fact that we, our brains are very
vulnerable. And to get back to your question about the stimulant,
you know, I think your brain was very vulnerable to it.
You know, you sort of may have had a predisposition to it.
You mentioned that you have, you're a little obsessive
and with the tick there, maybe you have this kind of,
you know, on the mild side of the spectrum OCD.
And I probably do as well, by the way.
So I also have avoided drugs for that reason in my life.
I'll drink a little bit of wine here and there,
but that's about it.
But I think most people don't avoid these things.
And we see these problems in relation
to not just taking a stimulant,
but any kind of environmental exposure.
Our own society causes so much stress.
And that's why I think we have these human conditions.
These are human conditions.
We try to model them in animals,
but most animals don't have these kinds of problems.
I've heard that you can,
an animal like a monkey in the wild can have depression,
a monkey's version of depression,
but I don't think it's really typical or human depression,
you know, and certainly it's not as prevalent as depression is in our human society
I think you know, we haven't evolved to manage the stresses that are in this society that we currently have and stimulants is probably one of them
You know, and I I suspect you were probably a little bit vulnerable
It's possible the stimulant led to an overdrive of your prefrontal and over-frontal cortex and even brought out a little
OCD behavior related to this super, this superstition that you had. So, now I believe that entirely.
And I also think, you know, that's why things like OCD and other kinds of psychiatric disorders
tend to present themselves in college when people leave their home and they're in school
and they're stressed and they're getting exposed to things that they haven't been exposed to before outside of the home.
And, you know, their brains aren't evolved and sophisticated enough yet to help them cope
with these kinds of stresses and how it manifests is in these kinds of conditions.
And I don't want to put a label on those conditions, but certainly could be a psychiatric disorder,
but could also just be lots of anxiety.
It could also be the kind of problems that you had as well. So, and I think the nuclear succumbens
and the cortical areas that we've been discussing that sort of send projections to these areas are
probably at least one of the main circuits involved in these kinds of things.
Well, I'm relieved it's no longer present, but I confess it, I always feel it close
by, along run helps. So, you know, being a slightly fatigued, not overly fatigued, but
slightly fatigued, seems to move out the kind of physical compulsion, but I tried to channel
it, never taken any medication for it, and here I am, still still going. I may call you
for a referral at some point, but at this point, I'm feeling
okay. Let's talk about nucleus accumbens and reward circuitry and the relationship between
OCD, reward addiction and to just give you a sense of where I'm headed with this is into the realm
of food related and eating related behaviors and disorders. Yes, I know you're doing some very important work there.
What is nucleus accumbens? I know we all have one or two, one on each side of the brain.
What roles does it play in healthy brain behavior and in pathology?
Yeah, the nucleus accumbens is a part of the brain, part of our reward circuits, the hub
of the reward circuits that I've always been most fascinated in.
There are scientists around the world, some of the leading, arguably some of the leading
scientists in the world, the father of addiction neuroscience.
I call him, although he tells me I'm nuts, Rob Malenka, who has studied the nucleus accumbens
since the beginning of his career
and who I worked with when I was at Stanford. Fabulous scientists and mentors taught me so much,
taught the world so much. Incredible. Yeah. First and scientist and physicianist. Yes, MD,
PhD, and brilliant in both ways, and very fatherly in a lot of way in terms of teaching people how to do science and be
good citizens as well. But the nucleus accumbens is an area that is also very complicated because it has
a lot of functions. It interconnects with many parts of the brain.
But there are some things about the Lucuis Accompanes
that are very consistent.
So when I started getting interested in reward
and what I could do as a surgeon
to try to improve how we manage rewards,
and what I mean by that specifically is,
if you have an urge for a reward, that's
a normal phenomenon. That's not something we're trying to stop. The issue is if you have
an urge for a reward that either puts you or somebody else at risk, it's probably a reward
we shouldn't have. I suppose you can say, well, depends on the size of the reward and
the size of the risk and how that fits into your societal norms. But for example, if you're obese and you have a doctor who is advising that you lose weight
and try to control your eating habits, you know, perhaps better food choices is an important
way for you to be healthier and not pursuing those better food choices.
That's an urge that we probably need to treat.
If you're a drug addict and you use heroin
or an opiate, consider the opiate crisis right now,
or cocaine, which is untreatable at the moment.
You know, that cocaine might make you feel, like you have some more energy that day to deal
with your work, or that opiate might make you feel better because life is stressful.
But the risk of doing those things is really high, in fact, potentially lethal.
So that's an urge that's treatable.
If you have OCD and you can't sleep at night because you're so nervous that you didn't
lock the door and you've checked 30 times, that's a reality for some people with severe OCD.
That's an urge we got to treat.
Eating disorders the same.
Eating disorders and obesity are obviously linked because of the relationship of a patient
with food, but they're also quite distinct.
Not everybody with obesity has an eating disorder, and obviously not everybody with an eating
disorder has obesity.
I'm particularly interested in patients that have been eating disorder as well as obesity,
because they're so heavily linked.
Not everybody with been eating disorder has obesity, but on average, most are overweight.
We are doing a deep brain stimulation trial at Penn where we're trying to modulate the
nucleus succumbence and understand it better in patients that have failed gastric bypass
surgery, the most aggressive form of treatment for obesity.
We believe they failed gastric bypass surgery because of binge eating disorder, meaning they
just can't control how much they eat. So their obesity is either related or even due to overeating, not some predisposition
to that body habitus.
You know, obesity is a phenotype, something that we can see.
Not everybody is obese because of the same thing.
So it's very important.
I was taught this by a close mentor and friend, Tom Watten, when he was the director of the
obesity center at Penn,
or the Center for Weight Needing Disorders.
And he said to me, you know, Casey, be careful with obesity.
You're interested in addiction, and I understand you're interested in the addictive tendencies
of certain patients with obesity and their relationship with food, but not everybody with
obesity has that problem.
And in fact, it's probably present about 20% of patients with obesity.
But now taking a step back, 20% of patients with obesity is still a massive problem of epidemic proportions.
And perhaps some of these patients have either some form of binging disorder or
I should say some degree of binging disorder, or at least loss of control eating,
which is common to both.
So that's a feature that I think eating disorder experts,
obesity experts, neurosurgeons,
obesity medicine experts,
would agree is common to eating disorders and obesity.
And I also believe it's common to addicts.
And perhaps patients
with OCD is sort of a loss of control disorder. It's actually not a disorder known by like
the DSM-5, some diagostic manual, but a feature, I should say, of these conditions that's
common. And that common denominator, I believe, can be restored, or at least this problem can be ameliorated or improved upon by a better
understanding and a tailored treatment to the nucleus accumbens specifically. We have learned in
mice that if you expose a mouse, now this is just a model, if you expose a mouse to high-fat food,
not food that they would normally eat, food that is like 60% fat, high
fat, it's like butter.
We've learned that if you expose them to food like that within two weeks, their nucleus
succumbence is not functioning like a mouse that was never exposed to that high fat food.
There's aspects of it that are hyperactive, I could say, and there's aspects of it that
are hyperactive or decreased activity.
But either way, it's not functioning properly.
And most likely, that function is predisposing continued behavior.
And then probably eventually leads to things like a habit that gets developed.
And that's a whole other area of these kinds of problems that is very complicated and poorly
understood.
But in any case, if we just focus on the behavior at hand, it seems that repeated
exposure to something like high fat food, a drug of abuse, or any type of reward that is a really
strong reward. In a way, it can hijack normal functioning of the nucleus accumbens. So the goal
of our invasive trial is to try to restore normal functioning to that Lucas
Accompanse.
In mice, there seems to be a signal that predicts when they're going to lose control.
And we can use that signal to deliver a real-time therapy in the form of deep brain stimulation,
just a brief amount of stimulation.
And that actually blocks the behavior.
And what's interesting is over time, that signal actually decreases in frequency, which suggests
some level of restoring normal function to that circuit in a mouse.
And we're trying to do that now in a human trial.
Fascinating. Where is the stimulation provided?
Because I would imagine that if one were to stimulate nucleosacumbins, you would see
a reinforcement of whatever behavior coincided
or preceded this stimulation.
So the stimulation, it's a brief delivery of stimulation anywhere between five and ten
seconds that is intended to just disrupt the perturbed signaling that's happening in
the nucleus accumbins.
There are disorders like depression, let's say, that I would describe as a bit more of
a state disorder.
And this is obviously oversimplified, because we know that there's fluctuations in mood
and depression as well, so don't let me oversimplify it too much.
But for now, let's forgive the oversimplification.
If we accept that depression is a state disorder
or maybe Parkinson's disease is a state disorder
recognizing that they do fluctuate,
these types of problems most likely,
but not definitely, most likely need
a continuous therapy of some form,
a therapy that's consistent, perhaps a therapy
that fluctuates with the condition,
but nevertheless still consistent.
Benjing disorder or OCD or addiction and Benjing disorder in the context of obesity.
A lot of these patients are functioning quite normally every single day.
It's just that intermittently throughout the day, there's brief interruptions in their normal functions
such that they have thoughts about food or the drug of abuse that they're really longing
to have.
And so we want to deliver a episodic therapy delivered at the right time and only at
the right time to try to interrupt the circuit aberration or the problem at hand that is going to lead to that dangerous behavior
and to kind of get the patient back on track to what they're doing.
I don't necessarily think that it leads to a reinforcement.
It's possible.
We have to study that more.
But rather, the goal is to just disrupt perhaps what is kind of habitual, or at least this
kind of recurring problem that is happening.
People that have been gene disorder, at least at a severe level, they tend to bitch about
once a day.
But they don't binge all day long, of course.
They have a moment, perhaps, when they get home from work and they're stressed, where
they might have a bout of binge.
What constitutes a binge? And I also want to know, does binge eating disorder come on suddenly,
meaning as an entire disorder? One day people wake up suddenly, they have binge eating disorder,
or is this, you know, a few too many buffets, and I'm being entirely serious here, you know
Unlimited food and a circuit gets flipped or kind of starts moving into the high RPMs so to speak
so how does it come on and
I'm actually surprised to hear that it's once a day. I would think just hearing binging this order I assume it's likeCD, which it probably fluctuates across the day as well,
but I would have thought anytime people around food,
they just simply can't control their intake of food.
Yes.
So what does this look like in terms of the onset
of the disorder, and then what do you think
underlies this once a day type of phenomenon?
That's pretty interesting.
Yeah, so severe binging disorder, these patients
will binge about once a day, it could be a couple times a day, but in general, it's not more than that.
Moderate is about three to four times a week, for example.
The reason I think that that seems surprising to you, and if you think about it, it is surprising.
But, and I agree with you.
But the reason for that is actually just in the definitions of the word.
And as a neurosurgeon in full disclosure, as I mentioned, I don't see these patients clinically. I see them for research trial purposes, and I try to understand the literature
around eating disorders. And I obviously collaborate with fabulous eating disorders
in these problems that are highly innovative people.
in these problems that are highly innovative people. But the word binge is a definition,
there's a definition to that word,
and you can't necessarily binge all day
because our stomachs are not big enough.
And so there's a limit to how much one can eat.
And to meet criteria for a binge,
you have to have a sense of loss of control.
You have to eat an enormous amount of food in a brief period of time.
And yes, generally that doesn't happen more than about once a day in a patient with severe
binge eating disorder.
However, they can lose control quite often.
And in fact, perhaps even at every meal, they might meet criteria for a bout of loss
of control, where they, yes, they may have lost control, but they might not have eaten enough
to constitute what we would define as a binge. And that would be in it. There's no specific
number to that, by the way. It's really just compared to their normal meal, you know,
perhaps it's 50% of their daily calories in that one brief moment.
So that's why I think it seems surprising that bingers aren't happening more often than that. 50% of their daily calories in that one brief moment.
So that's why I think it seems surprising that
bingers aren't happening more often than that.
What I would say is if we replace the term binge with loss of control eating,
loss of control eating could happen dozens of times a week.
And in fact, the patients that we're studying,
we've seen patients that lose control 20, 30 times a week.
And that's probably the term you have in mind when you're saying, you're surprised that
it's just one time a day.
And it's specifically related to the fact that these patients have to eat such a large
amount of food in such a brief period of time.
So it's hard to do that more than once a day.
I see.
You mentioned that some pre-existing anxiety might buy us somebody to have a binge.
I'm also fascinated by something I've observed before, which is when I was in college, my girlfriend had a roommate who we were where it was
bulimic and would binge and then purge. And often when she ingested alcohol, that would lead to a binge. Sure.
Which is kind of the opposite of anxiety when I think about alcohol as something that slightly
reduces prefrontal activity somewhat of a sedative or certainly a sedative at higher
dosages.
So this brings to something that you said, I won't say it as eloquently as you did,
that it seems like it's neither the case that anxiety leads to binging nor that hypo-reduced activation
of the forebrain and lower anxiety leads to binging.
It's this dysregulation of circuitry that the C-socago either way and it can throw things
off balance in both cases.
And that seems to be,
that seems to pose a problem.
It seems like it's a particularly tricky problem.
And kind of explains to me in my non-clinical awareness
why medication might be really hard to use
as a way to treat this,
but that being able to poke around in the brain
and assay in real time,
you know, how do you feel?
Do you feel like binging now?
Or do you feel further from the b like binging now or do you feel further
from the binging pulse?
Is that what you do with these patients?
Are they awake while you're stimulating the brain?
Because it's one thing to say,
I stimulate a brain area and that binging goes away
or partial relief or complete relief,
but how do you know?
Are they in there with a donut?
And you're tempting them?
So how do you actually know if a blading of brain area
is going to lead to relief or exacerbation
or no impact on this disorder?
Yeah, so there's a lot to unpack there.
I'll try to go one step at a time.
And if I miss something, please remember.
No, and I tend to ask these three part questions
specifically of neurosurgeons,
because I like to challenge you guys.
Because again, you are the astringent of neuroscience. Also, I'm just gonna take a moment to poke at neurosurgeons. I have a couple close friends who are neurosurgeons, and I can say,
Casey at Ren, I don't know if he can say, he's a friend, but I, of course,
I'm teasing there too.
Which is, first of all, they all have incredible hands, right?
They have, I'm not sorry, they all guard their hands with the kind of protection
that you would guard the tools of, the most important tools
are your hands.
And I'm going to say, I'm going to say, I'm going to say, I'm going to say,
I'm going to say, I'm going to say, I'm going to say, I'm going to say, They have, they all guard their hands with the kind of protection that you would guard
the most important tools of your trade.
So they're very careful with their hands.
You're not going to see them doing heavy deadlifts.
You're not because of the way that impacts the motor runs.
It's all about fine control.
So if your neurosurgeon does heavy deadlifts, you might want to consider getting a different
neurosurgeon.
It's nobody can put anyone out of work there. And then the other thing is that you all
tend to be very calm people, at least on the exterior. We'll return to this later. But
I do throw three or four questions out at once. So elevated autonomic arousal on alertness
as well as decreased autonomic arousal on alertness, both seem to be able to lead to binging.
And then there's this question of how do you know whether or not to stimulate or to
ablate or whether or not to leave a structure alone.
In other words, what does one of these experiments look like in the laboratory?
Yeah.
Sort of a clinic, excuse me.
Yeah, of course.
Yeah, these are questions I think about all the time.
And I do want to come back to the deadlifting comment.
But regarding, and you referred to this earlier as well, and I don't know if I addressed it
sufficiently either, is sort of like, what comes first here? Or how does this develop?
I think first of all, I like to understand these kinds of problems in sort of the construct
of what I consider to be a bit of a two-hit hypothesis.
So you sort of need like the concussion literature, you need, the second hit is can be devastating.
So if you have a concussion, you know, you want to only return to play when your symptoms
are gone and cleared by a physician.
So in the context of eating disorders, or let's say binge eating disorder, and first of
all, I didn't mention earlier, but this is the most common eating disorder effects anywhere
between 3 and 5% of the population.
And it's probably underdiagnosed in obesity, by the way, and if obesity affects 35% of
our population, most likely
binging disorder affects more than 3% to 5%.
But that's the current literature estimate on the prevalence.
So how do we develop binging disorder and is it related to this anxiety question?
You know, I think that there is a predisposition, that's the first hit.
I actually think all humans have this predisposition, just some have it more than others.
I don't think that we've evolved to live in a society where foods are so readily available
and enormously delicious and have so much sugar and fat in them.
Not that there's any particular problem with either of these micronutrients, it's just
the excess of it and how they're refined that I think is the problem.
There's high fructose corn syrup
and almost everything we eat.
It's in bread, I don't even know why it's in bread
sometimes, it's just kind of crazy.
So I don't think we're evolved to live in a society
that has food that's so readily available like that
and cheap, by the way. In fact, the cheaper the foods are sort of that has food that's so readily available like that.
And cheap, by the way.
In fact, the cheaper the foods are sort of the more refined
and palatable.
And I would argue dangerous to eat,
I think they change our reward circuits for the worse
and put us at risk for wanting more.
I tend to get a headache when I eat food like that.
And perhaps that's evolutionary advantage,
because I don't want to eat those,
because they actually do make me sick.
So in a lot of ways, I kind of wish that headache
on everybody, because perhaps we wouldn't have all these problems,
or that some of them would go away.
So I think that's the first issue,
is a predisposition to, or a vulnerability
to these types of foods, which we undoubtedly all
have to a certain extent, but some more than others.
And then the, and that's, so that's the first hit, is this predisposition in the context
of this sort of food focused society.
And then the second hit is probably a stressful event or a stressful life.
And it probably a recurring stressful event. I'm not sure this is published. I've never sat down
with like a eating disorder expert and had this question about how this develops. And I'm not
sure it's actually well known. But in a lot of ways, I think that that answer anybody would
agree with, that we need sort
of a predisposition in the exposure, the environmental exposure and the genetic predisposition,
but also a stressor.
And that stressor is probably one that's recurring.
And it's obvious in our society, these stressors are everywhere and how we can manage them
is often poor.
And I think we can all relate with that.
And then there's something else in the background
that I think is really important to mention
is that patients with these kinds of problems
are embarrassed because our society
doesn't think fondly of these kinds of patients.
Binging to sort of patients, they do tend to be overweight.
That's obviously a stigma.
Obesity is another stigma.
Then there's the opposite.
In a way, it's an opposite, by the way, from a phenotype standpoint.
That's anorexia.
I mean, that's another stigma.
And, you know, gosh, you know, not to make this about one sex over another, but when
girls are told they're pretty because they're thin, it just reinforces this problem.
And of course, you want to compliment people
and make them feel good about themselves,
but the problem is that in this vulnerable society,
that can lead to problems because people
start thinking, oh, I should be thin or thinner.
So I think that it's a little bit of a societal understanding that our brains are very vulnerable.
And I think that will really help changing society is hard.
And most of society is not, you know, ill-meaning.
It's all done by accident.
But that is the society that we live in.
So if we can try to improve that stigma and be kinder to people in that way,
I think a lot of these problems would get better.
People that are obese, that feel embarrassed by their obesity,
it doesn't help. It only makes it worse because they give up.
Same thing might be true for adoraxics.
So I really think it's important to consider all of these things,
and that's why it's so complicated.
And it would be so hard to do a well-controlled study to understand it better because there's
so many of these variables to control for that you really can't control for. You might
be able to control for them in a mouse's home cage, but not in the society that we live in.
So that's kind of my brief summary of how I would answer your first question. Then I think your second question,
I sort of take that as well,
how do you study such a complicated problem
in the operating room and in the clinic?
Because I mentioned the operating room
because that's sort of the first step here.
First, we have just a clarify,
we have an NIH-funded trial approved by the FDA for research to do this first in human
study.
We've treated two patients.
We have four more to come at Penn.
And in this study, it's something I've been working towards my entire career.
What we don't know is where in the nucleus accumbens, will we identify cells or regions that
seem to be involved in this sort of reward-seeking behavior?
I would call it a petitive.
It's kind of like appetite, but the word
a petitive is, I think, a good word to you. What part of the nucleus accumbens is a petitive?
Is the whole thing a petitive? Probably not. It's huge. In my world, it's huge. As a neurosurgeon,
you know, I target parts of the brain that are three or four millimeters in size. The nucleus
accumbens is almost a centimeter in size. Wow. I didn't realize it was that large. Yeah.
This over, it reminds me of discussions around the amygdala,
everyone thinks amygdala fear.
But amygdala's got a lot of different subregions.
And stimulation of certain areas in the amygdala
makes people feel great.
That's right.
And other stimulation of other areas
makes them feel terribly afraid.
Exactly.
And that shouldn't surprise us because when we treat patients
with Parkinson's disease for tremor,
if we're in one part of the subfilamic nucleus, we'll help their tremor. if we're in one part of the sub-filamic nucleus,
we'll help their tremor.
If we're in another part of the sub-filamic nucleus,
then ourologist is looking at me like,
why isn't this working?
And that shouldn't surprise us.
We already know that two or three millimeters deviation
or two or three millimeters away from where we wanna be,
and you might not have the result you want.
And that's probably also true
for these more limbic structures,
like the amygdala and the nucleus accumbens.
So, you know, regarding the nucleus accumbens,
we traverse some of the nucleus accumbens,
not all of it, in order to place the electrode
that we want to use to detect when cravings are happening,
for example, and to try to block the cravings
from leading to the behavior related to the reward seeking,
which is the overeating in this case.
So what we decided to do in the operating room was
to actually try to leverage a tool
that we use all the time when we take care of patients
with Parkinson's.
So with Parkinson's, a lot of these patients
not all have tremor.
And so when we place an electrode into this motor structure
to try to improve their movement disorder, we often can hear tremor cells.
And they sound, we convert their electrical signal to an audible signal, so we can actually hear it.
And it sounds kind of like the tremor looks like the frequency of the signal is the same as the hand shaking.
So, exactly.
And so the patient with Parkinson's is trembling.
Yep.
They're awake and you're poking around in a dedicated, careful way, of course.
One poke at a time.
One poke at a time with a very fine wire, a set of wires listening to the electrical activity until you encounter
some cells that are sending out electrical activity at a similar frequency.
Exactly.
And then you can stimulate them or quiet them and see if the tremor goes away.
So we are very confident that when we stimulate that area of, in this case, the sub-philemic
nucleus, we will make that tremor.
We will disrupt that tremor circuit, and that tremor will dissolve.
And it does.
That's why Parkinson's is so beautiful and inspiring from a certain tractable.
Yeah, exactly.
But what is the...
It makes us feel we understand the brain, at least in that limited way.
So what is the analog to tremor in terms of appetite and desire to binge?
Craving. So craving is a term that, you know, there's probably other terms we could use, by the way,
but that's the term we've chosen to use for a number of reasons. One, because people relate
with that term, people that have binge eating disorder or obesity, they, if you ask them if they
crave the answer will often be yes. If you ask them if they lose control or binge, they might not know what you mean, or they
might not actually feel out of control, even when they are.
But the word craving is relatable.
So we set out to see if we could identify craving cells.
In a patient with OCD, which is related, in fact we target a very similar part of the
brain, we try to identify cells related to obsessions. And we believe we did do that.
It was a single case study where we tried to optimize where our electrode was placed. So
we had some proof of concept that we would be able to elicit a sort of disease-specific
symptom in the operating room, assuming the patient could tolerate being awake.
Not everybody needs to be awake for this procedure, but at least for these first and human trials
where we're trying to establish where in the brain we need to be.
I think this type of approach is really critical.
And you know, by the way, none of this has been published,
but I think it's so important for people to know this.
So I am willing to share some aspects
of what we're trying to do.
But that's really the first goal of this trial
is to identify where the nucleus accumbens
we can detect these craving cells.
So we have to provoke food craving in the operating room.
That's the first thing.
How do you do that?
Oh, well, there are some somewhat validated ways to do that.
So for example, we asked patients to provide pictures of food
that they rate very highly as something
that they would typically crave.
And depending on the patient,
it might be something that's very salty,
it could be very sweet like a donut.
Donuts are good.
I love donuts.
Donuts are great.
You should try the cronut when you're here in New York City.
I just might, I try not to eat that sort of thing.
All the reasons they change your range.
It's worth one bite.
Okay.
Just try to stop yourself after that one bite.
So if I were one of these patients,
given the fact that the benches come on,
pretty seldom, once a day,
I imagine you have them come to the operating room
fasted or semi-fasted.
They're fasted, yep.
Okay, they're fasted, which probably
there are probably surgical reasons for wanting that too.
They kind of have to be.
And then you've done the craniotomy,
removed a patch of skull, lowered the wire into the nucleus
of combs, and then they are viewing pictures of food that they crave and thinking about it. Do they
have olfactory cues, smells of cronuts? Yeah, I would love to do the olfactory cues. We haven't
implemented that, but that is a great thank you, and I'll give you full credit when we do. I do
review the grant, but I'm so glad this work is funded because I mean,
this is when I, I'll make this time it's not a joke when I refer to you all neurosurgeons
as the astronauts of the brain. You know, this is out on the extreme edge of what we don't know
about how the brain functions and this is so far in a way different than giving a mouse access to high fat food. Not that I'm not being disparaging
of the mouse work, but so the person says, well I'm the patient in this case, so I
might say, you know, I'm hungry. A donut sounds really good right now. But craving
to me is like, I, you know, I'll cross the street, cross town, be late for my meeting, eat three of these.
Yes.
Maybe even hide that from somebody that cares about me, that doesn't want me doing this,
this kind of thing.
Hide it from myself.
Yes.
These kinds of behaviors, I'm projecting and I'm fortunate that I have cravings for things
in life, but donuts are not a more extreme of them.
So, this is all happening in real time,
and you're listening to the cells,
the same way you would listen to it
and search for tremor cells.
Exactly, same exact tools.
And you're doing that by recording
from a small population of cells in the area.
Yeah, in fact, we do get multi-unit activity,
which is multiple cells,
but we were to try to find one, a single unit to listen to.
One neuron.
Yeah, because it's just much easier to understand what that one neuron is doing versus trying
to listen to multiple.
And we also measure local field potential recordings, but those are analyzed, which is more
of a population response, thousands of cells.
Kind of a chorus of cells.
Exactly.
That we measure offline. The device that we use to
sort of treat these patients or intervene that we're studying, it can't do single unit recordings.
It's only doing these more population responses. So we correlate what we see in the operating room
at the single unit level to the population response, but we do that all offline. I can explain that in a moment.
But yes, so we try to identify these craving cells.
And because this is a feasibility study, and we can't be in the operating room searching
for hours and hours and hours, we do have some sort of, we have guidelines that we've set for ourselves, that we've developed with the NIH or the FDA to make sure that
what we're doing is feasible and safe as well. So we will spend a limited time trying to identify
these craving cells. But another sort of strategy that we think is really important is the effect of the stimulation.
So a lot of patients, and this gets to sort of your question earlier about what comes
first.
You know, a lot of people when they, when they binge or they lose control over food or
seek drugs, that moment of vulnerability is preceded by what we call a moment of sort
of pre-meal negative affect, which basically means right before they binge, they're feeling
down or they feel stressed or anxious.
And they compensate for that momentary symptom by binging or losing control over food.
Not everybody needs criteria for a binge,
so I try to specify that we are looking at loss of control eating
specifically just because the criterion of a binge is not as critical for us.
So what we want to be able to do is trigger stimulation when this craving is
detected by the device.
But we trigger it only when the craving is there, and we believe that if we can sort of
temporarily elevate their mood, ever so briefly, again, this is about five to ten seconds
of stimulation only, that perhaps that elevation in mood could actually sort of disrupt the
craving to binge cycle.
Maybe that's a habit, maybe it's not, but if you crave and then you binge, if we can interrupt that with this moment of feeling good,
that might be a really good therapy for a patient. And in fact,
when we do deep brain stimulation for obsessive-compulsive disorder, we can
fairly reliably induce a positive affect.
The problem is that it's not sustained, and the reason it's likely not sustained is
because with obsessive-compulsive disorder, we treat that condition with continuous
stimulation.
And it's not surprising that over time, the effect kind of goes away.
So when they're in the clinic and we turn the device
on, our patients feel great.
And we feel like we've solved the problem.
But they call us the next day and they're like,
you know, my depression came back or my OCD
hasn't gotten better and my mood's back to where it was.
Can you get it back to where it was yesterday?
Because that felt great.
The brain loves homeostatic regulation.
It does, and it does not like to shift patterns.
Regression to the norm.
Right.
And I think there's sort of a tolerance effect there.
That is limiting the effect of continuous stimulation.
And actually in a mouse, if you do continuous stimulation,
the sort of blockade of binge eating goes away. So actually in
a mouse we've actually demonstrated, we published this not too long ago in
PNAS, that if you deliver stimulation intermittently and only when sort of
a craving signal is detected, so to speak, that effect will be the most
robust and durable.
But if you deliver it continuously,
actually the benefit goes away over time.
So I've always encouraged my colleagues
to consider more of an episodic stimulation approach
rather than continuously brain stimulation.
But of course, that's for these more episodic conditions.
Whereas these more quote unquote state disorders
as I oversimplified earlier,
they might need more of a continuous therapy.
So that's definitely subject for a lot of research in the future. quote-unquote state disorders as I oversimplified earlier, they might need more of a continuous therapy.
So that's definitely subject for a lot of research in the future.
So in any case, the goal in the operating room was to identify a craving cell, deliver
stimulation safely, but also to capture a moment of elevated mood.
We were able to do that as we are in our OCD patients as well.
And also to get an interoperative CATS game, we have devices now in the operating room that
allow us to get imaging in real time. They're fabulous tools that we didn't have 10 years ago.
So we can confirm accuracy.
You know where the, you can see where the electrode is.
Exactly. Exactly. You know with 0.5 millimeters of error, so super precise.
Or as precise as we think we need to be.
And we use connectomics.
So there's a tool in brain imaging called
a cartography where we can actually measure circuit connections.
It's an indirect assay, but we believe it's powerful.
It has its assumptions, but like anything in science.
But we can actually map out where the nucleus accumbens
connects to the prefrontal cortex,
sort of the cortical control and inhibitory control pathway,
and where that pathway intersects with the nucleus accumbens,
and we can target that area structurally.
So those three goals of the surgery,
we aim to set out to accomplish,
and we believed if we achieved two of those three,
that we would have a successful result in our early trial.
Amazing.
Given that at least to me, the non-clinician, the anorexia is the mirror image of binge eating
disorder.
And, at least from what I learned, one of the more deadly psychiatric conditions.
But also quite common.
Is it possible that nucleus accumbens
this so-called reward circuit
is also involved in anorexia,
but somehow it is the resistance to eating
the craving of the fasted state
or something like that that's being reinforced.
And I asked this for two reasons.
One, because I'm genuinely curious about anorexia,
I've observed anorexia in a number of people I know, and it's a striking thing to see
somebody just resist food despite all better knowledge of the fact that they're getting
quite ill, maybe even at risk of death.
But the other reason is that if, in fact, nucleus acumbens is the site which can harbor cells to promote
craving and craving of fasted states, so to speak, then that I think might tell us something
fundamental about how the brain works, which is that structures don't control functions
per se, structures control dynamics of interactions. Sort of like a orchestra conductor
has a certain number of operations that they perform, but really their main function is to
coordinate the actions of a lot of things, not to make sure that the violin's always play in
a certain way alongside the obos. You can tell I'm not a musician here.
You actually have an appreciation for the ob voice. Those usually get left out.
What's that the old voice?
Yeah, they usually get ignored.
My partner plays the old voice.
Oh wow.
Yeah, so I think it's a great analogy, by the way.
You know, I make this statement.
It's a little controversial, but I actually think people would
understand where it's where I'm coming from across all of these sort of
sub-specialties of medicine.
But I actually think, especially with obesity, remember, it's a phenotype that's reflective, often, but not always, of a behavior. But if you consider patients that have obesity,
and they exhibit some sort of compulsion towards food, so they overeat despite the risk of it,
I think those kinds of patients are more similar to anorexics than they are different.
Anorexia and obesity are both phenotypes that are,
at least in this specific case of obesity and in anorexia,
a result of a compulsion to either over or underneath,
despite the risk.
These types of compulsions are driven
by societal pressures, brain vulnerabilities
that are probably more similar than they are different.
They just happen to manifest differently.
Why they manifest differently is probably related
to each patient's predisposition, or perhaps preference.
That's hard to know.
Like you, I have a personal connection
to these eating disorders and a rexia included.
And, yeah, I think it's very scary.
And it's a condition that often instills fear in psychiatrists, because I think, you know,
not everybody, by the way, I mean, we have some phenomenal psychiatrists that I work with,
both at Stanford and at Penn.
They're also involved in my obesity study that take care of these patients.
I mean, these are heroes, but there's a lot of psychiatrists that are not in this domain
that find anorexia scarier for the reason you said.
It has the highest mortality of all psychiatric conditions that includes depression, because
not only can these patients die of suicide, but they die of metabolic complications of being
underweight.
So it is a scary condition.
I relate with that.
I am trying over time to bridge what I'm doing
in obesity and bingeing disorder to anorexia.
For two reasons, one, because I think these problems
are more similar than they are different,
and two, because of the need.
And I think we're well positioned
to sort of tackle anorexia
using similar approaches, not identical,
but similar approaches.
The nucleus accumbens has been studied
in patients with anorexia in China,
actually my first postdoc,
who I had the honor to train
when I was at Stanford
as a neurosurgeon in China.
And when before he came to me, actually was involved in a trial of anorexia that had some
benefits.
And there are studies in Europe and elsewhere that have examined preliminarily the effects
of deep brain stimulation targeting the nucleus accumbens for anorexia, colleagues of mine in Canada, under acilisados, a wonderful neurosurgeon
scientist has been studying the effects of going after area 25, which is directly connected
to the nucleus acumbens by, you know, it's a monosynaptic connection. So in a lot of ways,
you know, perhaps delivering stimulation there could
be very similar to delivering stimulation with the nucleus accumbens. That's all part of one
critical inhibitory control circuit. He's seen benefits as well.
So I definitely think there's some evidence that this is an area that we need to be studying.
I think our more episodic approach with response stimulation going after a signal in the nucleus accumbens that
seems to be related to the compulsion to withhold from eating.
I think it's what we will be trying to accomplish in our study.
It's right now just being conceived, though.
These studies, they move so slowly because you have to get a grant.
That grant gets reviewed by the NIH six months after you submit it, often gets rejected because it's too innovative
and too high risk, so then you have to edit it and decrease the risk. So it takes my obesity
study took two years to get funded. And I worry about that time frame because that's
a lot of time for patients that are actually to suffer that I might be able to help at least
in a small sample of patients. So, but that is the nature of how these things go.
You also have to get FDA approval to do these kinds of things. We try to do all of this in parallel.
It's an enormous undertaking. And in a lot of ways, we're starting from scratch, but in some ways,
we have some preliminary data to go after this. So, my hope is in about a year, we'll have a similar
trial for anorexia at Penn. So, so more to come on that. And we're not the only lab that's trying to go after it because of the
clear need. So what is the status of non-invasive brain stimulation, ablation, and blocking activity
in the brain? I get a lot of questions about trans cranial magnetic stimulation. I've actually had
that done as a research subject. Sure.
And I was at Berkeley Richivery's lab, put a coil on my head.
I was tapping my finger in concert to a drum beat.
And then all of a sudden, because of the stimulation,
it was impossible for me to keep time with the drum beat.
That's cool.
It's a pretty wild experience to not have motor control
and then to have motor control returned at the flip of a switch
when someone else is controlling the switch is makes it especially eerie. So my understanding is that
transcranial magnetic stimulation is being used to treat depression and a number of other brain
syndromes noninvasively so no drilling through the skull. Surgeons don't like that. Surgeons love to cut and drill with purpose,
but they do with purpose.
But my understanding is that the spatial precision
isn't that great.
Ultrasound is something I hear a lot about these days.
And my understanding is that ultrasound
can allow researchers and clinicians
to stimulate specific brain areas,
perhaps with more precision.
Maybe you just give us a coverage of what those are being used for.
What are your thoughts on these forms of non-invasive, meaning no flipping open of a piece of the
skull type brain stimulation and blockade of brain activity?
Sure. Yeah, and I wanted to clarify also,
these surgeries generally don't,
by the way, require a full craniotomy.
It's usually just a small opening
about the size of a dime in the bone,
so just to clarify, but that painless, too, right?
Well, usually without pain.
Yeah, they're a little bit of scalp numbing.
We give a scalp block,
and the patients are getting IV sedation,
so they, in general, don't feel anything. And if they do, they tell me, and we patients are getting IV sedation, so they in general don't feel anything.
And if they do, they tell me and we give them more local anesthetic, but they're usually
asleep during that part.
So it's minimally invasive, but in a lot of ways, there's no such thing as a minimally invasive
procedure in the brain.
It's kind of so loud here you say that.
Oh no, I am not one of those neurosurgeons that you've probably encountered, and we have
mutual friends that, and these mutual friends are some of my favorite people in neurosurgery
and they probably actually think more like me than the not, but there are neurosurgeons
that you're absolutely right.
And this is true for all surgeries.
They really, in a lot of ways, they think what they do is sort of the ground truth or closer
to the ground truth.
And I get that.
You know, probing with purpose.
I actually really like that.
I'm going to use that if you don't mind.
It's just describing what you do.
So, yeah.
But I actually have always said this.
I've said it publicly.
I've said it to my boss.
I've said this to my team.
We need to embrace non-invasive approaches. Some of them are a little fluffy.
Fluffy in that we don't understand how they work.
We don't necessarily understand how deep brain
is too much to work by the way.
But because we don't know exactly how they work,
they're not as precise as we would like them to be.
So we have work to do there.
And I actually think that work is doable and actually underway.
At Stanford, we have great collaborators that I think are doing this. to do there. And I actually think that work is doable and actually underway. You know,
at Stanford, we have great collaborators that I think are doing this, people like Nolan
Williams and Connor Liston at Cornell and others. So we, I think that TMS, Transprenom
McNanon Extimulation, it is FDA approved for depression, by the way, it's also FDA
approved for OCD and for nicotine addiction.
Where do they put the coil for those three pieces?
Or more or less?
Yeah, so they put it over, it was always on the scalp and over the frontal lobe.
And there's different parts of the frontal lobe that have been demonstrated to be a little
better or a little bit worse.
But what the FDA has approved for depression, I believe is similar to what's been approved
for OCD, but for addiction, I believe it is a different target, but we'd have to ask
our TMS experts on that.
Can they direct the trillions of churnium-inion stimulation deep below the cortex?
They try.
And we're actually studying this in OCD patients now.
As a part of our invasive trial, we are trying to pool patients from a TMS trial
that's in parallel to what we're doing, all funded by the Foundation for OCD research,
where we believe we can use TMS to define a circuit that if modulated, it proves OCD
albeit temporarily.
And in those patients, if it's temporary, they would be appropriate for an invasive study.
So something we're actively working on, I've always believed that neurosurgeons need to be part
of the discussion with these non-invasive approaches. We don't need to do them.
But I think we can help make them more precise and to probe non-invasively with purpose.
Rather than this more kind of, I don't know, a non-invasive blast effect, I just can't
imagine how that is going to be as effective as probing with purpose, but you can do that
non-invasively as well.
And I think we need to do better in that way.
I do believe that's possible and I think people are actively trying to do it.
Getting deep in the brain with TMS, I think will always be hard, but you can get there indirectly
by using connectivity assays and targeting superficial structures that have high connectivity
to deep structures. So for example, perhaps one day there will be a TMS target for anorexia
and obesity. If we are scratching the surface with invasive approaches to these problems,
we're even doing less with the brain stimulation. So we have so much work to do there. Eating
disorders and TMS have been so sort of scarcely studied or there have been
so such little research done in that space. So it is an area that we need to work on.
For the obvious reason, for example, in a patient with anorexia, just thinking practically,
placing a device in a patient who is significantly underweight might not be the best approach,
wound erosion
and issues like that could come up. So developing a non-invasive approach, I think, is critical.
The problem is, where do we target? And so, the only way to answer that, I think, reliably,
is to accept that we have to get into the brain before we're out of the brain. And with these
kinds of conditions, we're only just starting to get into the brain. You know, so I worry that we're a long way away from a non-invasive approach that really works
consistently. I'm just starting to trouble. I want to make sure we touch on ultrasound, because
yes sure. But historically, it seemed that there was a bit more permission for people to probe around in the human brain.
I've sometimes refer the podcast to some of these papers that were done, allowing patients to self-stimulate in the brain.
These are worked on in the 60s, and now his name escapes me, Robert.
Anyway, there's a couple of papers published in science, allowing patients to stimulate a couple different brain areas asking which ones they preferred.
And I was always shocked and slightly intrigued by the fact that the brain area that all
three of these patients, who I don't think had any syndromes.
I think they volunteered for these experiments.
I don't think you could do this anymore.
Yes.
Regulatory.
Yeah, I think it was not the same as it is now.
It has changed, fortunately.
But they, all three of them seem to like some midline philamic structure, which for those
listening is just an area kind of in the dead center of the brain, more or less, that evoked
a sense of kind of frustration and anger, which surprised me because I would have thought,
oh, it's Robert Heath, his experiments, rather than patients prefering to stimulate areas
that evoke laughter or joy or a feeling of drunkenness
or delight.
It also explains a lot of what I observe
in social media, the sort of people repeatedly
engaging in battles that are kind of trivial.
It seems like frustration and anger
might have its own reward circuitry.
Anyway, I don't want to go too far down that rabbit hole,
but it's a deep
one. It's a deep one. And kind of gets to our nature as humans and what we find interesting
or rewarding. But the inability to probe around the brain in a safe way without the need
for somebody to be very sick would be I think would be
enormously powerful and at least to my mind if I were in charge which I'm not
would offer the opportunity to really come to an understanding about how the
human brain works without all these issues of how to translate for mouse
studies and again there's huge value to animal studies as we both agree but so
many of the things that
we want to know about the human brain involve asking the person, hey, what do you feel when
that set of neurons is stimulated?
What don't you feel?
And a mouse, we can ask and ask, but they're not going to tell us something.
They do tell us that they're not going to tell us in English.
So how do we overcome this challenge?
But first, ultrasound, or if you prefer, after ultrasound, is ultrasound gonna be really useful
towards solving these clinical issues
and these basic issues?
Yeah, so I think let's start with ultrasound
and then we'll come back to it.
So ultrasound right now, trans cranial magnetic guide,
magnetic resonance guided focus ultrasound.
So this is an FDA-approved method
to deliver an ablation to the brain noninvasively.
There are researchers, myself included,
that are trying to use transcranial magnetic guided,
magnetic resonance guided focus ultrasound
or MRI guided focus ultrasound
to use it in a modulatory way, not just as an ablation, but to drive neuronal activity, or inhibit it, perhaps, we're still learning how to do that.
There are trials that are trying to understand if you can use ultrasound to open the blood
brain barrier so you can deliver a medication to that specific area, perhaps for a brain
tumor or something like that.
So it's a very exciting field,
and it is FDA approved for tremor right now,
and so I actually do it routinely
for patients with tremor with Parkinson's
or essential tremor.
And so I love doing it.
It's often just kind of a miracle
because there's no incision.
I don't have to place an electrode into the brain to achieve a similar result.
How early into the pathology of Parkinson's can someone think about approaching this?
So for instance, if somebody has a parent or a sibling and they're developing some resting
tremor, obviously they should talk to an neurologist but neurosurgeon, but this non-invasive
approach could be incredible for them as
supposed to just take only taking drugs to increase dopamine levels.
Yeah, so depending on the reason you have tremor, would dictate the kind of medication you would use.
It could be Parkinson's, but if it's not, it might be a central tremor. By the way,
central tremor is 10 times as common as Parkinson's. Really?
Central tremor is the most common neurologic condition in patients over the age of 70.
We often aren't aware of that. People with the essential tremor feel they have their
forgotten disease because there's no Michael J. Foxx for essential tremor. I sent a letter to Bill.
Sorry, is it essential tremor or essential tremor? Yes, and I think he's actually disclosed that he has it, and
I've hoped he'd become a champion for patients with a central tremor.
Sandra Day-Conor does as well, and she's also a public about it.
But I was not able to get them eager to become the champion for this condition.
But like Michael J. Fox, these patients need a champion like that.
But unfortunately, it's a bit of a forgotten disease.
Nevertheless, because of the FDA approval of Focus Ultra Sound for tremor, I know they're
trying to get some attention for sure.
And it's fabulously effective for these patients.
It treats patients on one side, usually they're dominant hand or they're worse hand.
And it really speaks to the fact that, wow, you can deliver
non-invasively an ablation to the brain in a hypothesized zone
that we think is related to the problem at hand.
And at least with tremor, it works really well.
Could this be effective for psychiatric disease, obesity,
eating disorders?
Well, perhaps actually that would be the ideal.
The problem is we don't know where to do the ablation.
There is a trial that we would like to do for OCD
where we would deliver an ablation
to the same area of the brain
that we've been delivering ablations to for years
for patients with OCD.
And it helps a bit, that's called a capsuleotomy.
But really the outcome is probably to be about the same.
It's a nice method because it's not invasive,
but we need to find a new target for these conditions.
And because of the common denominator of the urge
despite the risk, sort of that compulsion,
perhaps it could be the same target.
I don't know.
But I would argue we need to do these modularatory experiments either with a device
or with invasive recordings to better understand
where these problems are coming from,
to define where we should do an ultrasound treatment.
So you're right, historically,
without much regulation, we've probed the brain.
The problem, we can't learn a lot from those experiments now,
well, in this way at least, we don't know exactly where those electrodes were.
We didn't have MRI scanning or high-quality cat scanning to know where those electrodes were with certainty.
And we know two or three millimeters matters.
And we also didn't have the tools to place electrodes
in a precise way back then.
So unfortunately, we can't learn a lot
from those experiments right now.
So we're sort of redesigning them.
And there is a way to do it now.
Patients with epilepsy benefit from this all the time.
There has been a revolution in America.
It was in Europe before it was in America,
where we would do stereo and cephalography,
which is basically like doing an EEG of patients with epilepsy, but within invasive electrodes,
and we would place tiny little wires less than a millimeter in diameter all throughout the brain
into parts of the brain that we believe are involved in seizures. And we would admit the patients
to the hospital and figure out where the seizures were starting and propagating. And then,
we could stimulate those electrodes to see if there was a symptom that was important.
And I try to identify a region that we thought we could either remove surgically, ablate
with a laser or put a stimulator in it, perhaps.
That's commonplace now for epilepsy.
And it works extremely well, and it's very safe.
Of course, it's still a brain procedure, but the complication rate is surprisingly low,
quite honestly, for the amount of electrodes that we place.
And it's extremely well tolerated.
Most of these patients leave the hospital and they don't even feel like they've had surgery.
So there's actually a lot of interest in using that procedure to study mental health disorders.
We are trying to do it for patients with obsessive compulsive disorder.
We're awaiting an FDA decision on that.
But actually, I credit our colleagues at Baylor and at UCSF for studying this already.
We have fabulous colleagues at UCSF that have studied depression using
this type of approach, a mutual friend of ours, you know, Eddie Chang, who's a
wonderful friend and colleague, somebody I've emulated for many years as well,
and the psychiatry team at UCSF have worked together on this sort of bringing
together the epilepsy technique and the psychiatry expertise to study how we
could better target electrodes in depression. And I'll tell you, if they have a consistent target,
perhaps there it becomes an ultrasound target. But right now the approach is a bit more reversible
because you can always shut that electrode off or even remove the electrode. If perhaps it's not in the optimal location to treat the depression.
But actually after a large volume of cases perhaps they could pool that data to develop a new ultrasound target for depression.
I think that would be fabulous and probably is their long term goal not to speak for them, but that would be something that I'm sure is on their radar.
And a bailer's trying to do the same thing for depression.
Their approaches are a little bit different,
but a similar tool to try to understand depression.
And we're working with all of these types of colleagues.
Some of these are our friends to bring this to OCD as well.
And it makes sense to try to do this for addiction
and obesity and anorexia.
You might ask, well, why are you doing this for obesity
right now in our study?
And the reason is that we've developed a target for obesity
and binge eating disorder developed out of mice
that we believe is relevant for the human state,
because you can model this problem in a mouse, a bit better than you can model depression or OCD. So we feel like we can rely
on the preclinical studies more. Whereas with these perhaps more, I don't
want to say more complicated, but more human mental health conditions that are
hard to model in a mouse, you really have to study it in the human. And you can
perhaps start in an epileptic patient,
a patient that has electrodes and try to provoke a depressed
date or study epileptics like Dr. Chang has done
that have comorbid depression, for example.
And that can really validate this approach as well.
But in the end, it's getting into the human brain
that we need to do in the disease specifically,
that will eventually lead to a non-invasive
approach, either a lesion or modulatory approach.
Modulatory would be like TMS or lesion approach would be with ultrasound.
I couldn't agree more.
Meanwhile, because there are many, many millions of people suffering from depression, eating disorders, Parkinson's
and essential tremor, et cetera.
Well, first of all, I should say, based on everything you've told me thus far, it's amazing
to me that any pharmacologic treatments work because of how systemic they are in impacting
serotonergic neurons over here and dopamineergic neurons over there and not targeting any specific batch of cells.
It makes perfect sense as to why all the side effects exist.
But earlier you said something that really grabbed my attention.
I want to come back to, which is that if people can be made to feel
or bank themselves feel just a little bit better,
a little less anxious, just prior to a craving episode
or a binge episode.
Maybe even if people can become better at detecting their own internal states, and when they're
kind of veering toward a binge or veering toward using a drug or maybe veering towards suicidal
thinking, based on what you said earlier, that those kind of pre-behavioral states,
the kind of drift on the steering, those some powerful levels of awareness,
at least for now, until we have specific sites in the brain that we can target non-invasive
methods that could be deployed to millions and millions of people, seems like that awareness seems like maybe among the best tools that people could develop.
Yes, 100% agree with you.
So for the person with OCD who suffers from anorexia or binge eating disorder and to their clinicians,
I just want to highlight that you said that.
I mean, again, I'm not a clinician.
I always say this.
I don't prescribe anything.
I profess things. And, but awareness of one's thinking seems immensely powerful in this context.
Yeah. And after all, it is the clinical probe that you use because the, if, let's say, the patient
were to lie to you about their experience of what happens in their mind
when you stimulate, you could, basically,
the whole thing, the whole surgery,
the whole procedure could go badly wrong.
So it's up to the patient to be, of course, honest with you
and their incentivized to do that,
but to be honest with themselves about,
ah, you know, I've gone all day without a binge,
but you know, the smell of a
donut or the thought of a donut is starting to have a particular allure.
That awareness seems like an incredibly powerful thing to own and to build and cultivate.
Yes.
I've always thought that if we can improve awareness, we can improve outcomes.
I think that's probably true for many of these patients.
The problem I think comes down to the fact that some of these patients are so resistant
to treatment.
The patients that we see as a surgeon, for example, are the patients that they've tried
cognitive behavioral therapy, certainly have tried medications, they've tried behavioral
management.
They are aware of their problem, and they've shown that to us.
They can tell us when they're craving
But despite the craving and despite being involved in this invasive brain surgical trial
highly, you know first in human novel study
Which I think we'll have a positive effect, but it's still experimental
They still can't stop themselves. So they're
Sort of as made aware as could possibly be, did I use
grammar there correctly? I think so. They're as aware as they could possibly be and they
still lose control. We've had this studied in the lab, so we will bring patients to the laboratory
with this implanted device to try to provoke this electric graphic electrical signal
that can be detected by the actual device that will stimulate them
when they're at home.
But before we actually initiate stimulation,
we want to see can this device detect this craving cell signal,
which is going to be different than what we saw in the operating room,
because that's a single cell.
But these devices, these electrodes, are about a millimeter in diameter,
instead of like a tenth of a millimeter, which is what we use in the operating room.
So they're only hearing or detecting, I should say, thousands of cells' responses.
And we actually have a way to provoke benches, it's called a mood provocation.
It's very well validated.
It's a little bit like provoking seizures
in the epilepsy monitoring unit.
But here in these sort of
psychiatric monitoring unit
or the food monitoring unit,
we actually have a psychiatrist
and even sort of specialist common
induce a mood that is related to
each patient's sort of self-described binge episode. Does the psychiatrist
come in and provokes a feeling that can evoke the negative behavior?
That's exactly right. So that we can video and synchronize the video to the brain signal
recordings. The patient is all wearing eye trackers so we can see what they're eating at all times
and what they're looking at specifically.
And that allows us to have the best temporal resolution
possible to understand what is happening
right before the bite.
And even under video surveillance,
there's one way mirror in a laboratory setting
when patients are very well
aware that they're there to be studied if they're going to binge. They still do.
And we believe they do because they just can't control it as aware as they are of
it. And it's probably because they're the most severe. So I think if we can
improve awareness, not just the societal awareness that I was talking about earlier,
but the patient awareness around their problem,
I think that could be a powerful way
to help so many of these patients.
And that's sort of the role of cognitive behavioral therapy.
The problem with cognitive behavioral therapy
or I should say the limitation of it,
I actually don't have any problem with it.
I think it's a wonderful treatment.
Is that if you stop it, many of these patients
go back to their old behaviors.
I don't wanna say old habits,
but it might be a habit, but the old behaviors.
And so that's the problem.
It's not necessarily lasting
in the absence of continued cognitive behavioral therapy.
Some people can benefit from it long-term,
but some can't.
But I think in the less severe patients, improving awareness key.
But in these really refractory patients, this is kind of like, this is the disease, despite
the awareness they can't control themselves.
And that's what we're trying to restore is that improved ability to control their behavior.
Do you think there's a role for machines and artificial intelligence here?
There are a couple laboratories up at the University of Washington that are using particular
signature patterns within voice to try and help people who are suicidally depressed know
when they're headed towards an episode before they even can consciously know.
So this gets right down to issues of free will and whether or not machines can be smarter
than we are.
But you know, one could argue that some of the search algorithms on Google and other search
engines are actually more aware of our preferences than we are.
Basically what these are, these are devices that are listening to people talk all day.
They're also paying attention to patterns of breathing and how well people slept, etc.,
integrating a huge number of cues,
and then signaling somebody with a yellow light,
like, you know, you're headed into a depressive episode,
and the person might say, I feel fine,
or I feel pretty good, this is kind of baseline state for me,
and they say, this is where you were preceding the last episode
that took you down a deep dark trench
and it took months to get out of.
I wonder whether or not some of these devices could help with the sorts of things that we're
talking about today.
Yeah.
I think so.
I've always said we have to get in the brain before we get out of it.
And if we get in the brain and understand what these signals look like, we'll know what
those non-invasive signals are.
I think it's possible that we are scientifically
sophisticated enough to use machine learning
and sort of this kind of bot technique
to anticipate when somebody is going to be highly impulsive.
You know, suicide is the most dangerous impulse.
It's something that is immensely a focus of the lab
is impulsivity.
We've talked mostly about compulsion.
Compulsion being going after a reward
or the urge to spite the risk.
Impulsivity is similar, but different.
It's kind of going after something,
a little bit, if you model impulsivity in a mouse, it's related to going after a food reward without
the sort of paired tone that the mouse is supposed to wait for.
The mouse doesn't want to wait anymore.
They just go after the food.
I've been that mouse.
Yeah, we all think.
We could all relate with this to a certain extent.
Again, it's the spectrum.
So in any case, I'm not a sequitur, but I certainly think that there is a way to use our own
body's physiology to anticipate when these impulses are coming online.
How best to do that, I think,
were just scratching the surface,
but these are the kinds of solutions we need.
These are, some of these problems
are of epidemic proportions,
largest public health problems in this country,
in this world, obesity, opiate crisis, depression,
suicidal, I mean, that's like a third of our country,
maybe more, probably more.
And I think about it.
And a colleague of ours at Stanford Psychiatry told me something that still just blows
my mind, which is that something like 75% of the antidepressant and anti-anxiety medication
that exists in the world is consumed in the United States.
It's amazing.
Which is, I mean, that's an outrageous number.
Yeah, we do have an obsession in this country for pharmacy.
You know, and the pharmaceutical industry is very powerful here
and probably related to some aspect of capitalism.
I'm capitalistic and it's just like everybody else.
But I do worry about that a little bit.
But, you know, we tend to over-prescribe
and I think we, as patients tend to over-prescribe, and I think we, as patients, tend to over-want medication.
We like quick solutions, and sometimes medications provide it sometimes not, or they're often
just a band-aid.
It depends on the problem, of course.
But I agree that we need scalable solutions.
I'm a neurosurgeon.
I'm only going to be able to treat the most severe of patients
with these problems. We've only done about 200,000 deep brain stimulation surgeries ever.
So, the problem we're talking about here is 50 million Americans. There's no possibility
that surgeons can address that problem, But we could help inspire an initiative
to go after that kind of problem or help make it more rigorous. Because the last thing
we need is some sort of wearable fancy tool that waste people's money and time. We need
real therapies for these things. Not that these devices that we're discussing are not.
I think actually there's lots of promise.
We use machine learning in the lab all the time.
I'm not an electrical engineer or the computational neuroscientist doing this type of work.
I just helped develop the hypotheses around it, but I definitely think there's a future
for it.
I suspect we're scratching the surface on how best to do it.
Let's talk about your hands.
Yeah.
Sure.
All the neurosurgeons, I know, are very faithfully protect their hands.
Let's talk about hand insurances too expensive.
That's right.
But I'm guessing that you all are not the ones to reach into the garbage disposal, even
if your eyes on the switch to make sure that it isn't going to get turned on. They're just too precious. They are your livelihood.
And earlier we talked about deadlifts. There are other forms of exercise, things like tennis,
they're drawing and painting a full range of things that one can do with their hands,
use your imagination for this. Is it true that neurosurgeons don't do any really heavy grip activity because it can
refine the motor circuits in the brain and elsewhere that can throw off their neurosurgery
game?
I would say that many neurosurgeons avoid activities that put their hands at risk.
Another one, by the way, there's an annual softball tournament that neurosurgeons come
to in New York City in Central Park.
With a very softball.
No, I'm just kidding.
Actually, it's actually a very typical hard softball.
I don't know why they call it softball.
And actually, two close colleagues of mine
have gotten injured at that tournament.
Maybe this is a, it's also, I must say,
and here I'm poking fun,
but for those of you who are going
to the medical profession,
it's also one of the more, how should I say this?
Well, I'm just gonna say it.
There's a steep hierarchy of training in neurosurgery.
Yes.
There's a certain harshness that's been conveyed to me
about the training, much like astronaut training,
to be totally fair.
And so maybe this is a tactic to weed out
either the younger or the older generation.
This is evolution, right?
We have to evolve and target weed.
We need medical to get out the week, I guess.
Well, I could say that one of the individuals
that got injured is one of the more senior surgeons
that I work with now and is one of the best athletes
that I know and he's definitely not weak,
but you can get injured playing these sports.
And that being said, I can tell you briefly is,
I think that, you know, it's funny,
my mother came to me recently, she is osteopenia
and she told me her doctor told her,
she's not allowed to do deadlifts.
And I was like, okay, that's fine.
I'm not telling you you should do deadlifts.
I just don't exactly understand the relationship.
But I can't say that I do think, I'll give you a little story here.
The reason why I'm being a little hesitant to confirm that I agree with you on the deadlifts
is I, when I was the deadlifts is I
when I was operating this was when I was at Stanford University operating and we as I mentioned earlier we get an intraportive CAT scan to confirm accuracy for our lectures I do this for all
of my surgeries. When I was reviewing that CAT scan the X-ray technician looked at me and said
whispered into my ear he's like your, your posture is really bad, it's embarrassing.
Your physical posture while doing your surgeries.
Yeah, and I looked at him and I kind of wanted to say,
I won't curse, but I've been doing it
intermittently during our conversation
because he made me realize that I really did have bad posture.
And we kind of had a little brief aside
and I learned he was a personal trainer
and his name was Zach and he
You know, he said to me, you know your posture is weak because your posture is poor because you're weak
You need to strengthen your body and strengthen your core. I was like how he's like powerlifting
And I'm like I'm a little hesitant to do this and I'll tell you I started very slowly
And I can't prescribe powerlifting to everybody
for the exact reason you said.
And I've gotten hurt doing it, by the way.
But I do think, I wish I started a little younger.
And I would argue that with close supervision
and very well, if you have a very experienced trainer,
which I would argue if you're a neurosurgeon
or an astronaut, or have a highly specialized profession where you need your limbs to function
dentists, things like that, if you're going to take something on like this, it really needs
to be extremely carefully supervised.
And I can tell you that my trainer had a profound impact on my life and my posture and my physical
health.
So we did deadlift.
I'll admit, so when you brought it up, I kind of chuckled to myself, but yes, I have
gotten mildly hurt deadlifting, but it was when I was doing it by myself and I was kind
of cocky and I wasn't paying attention.
When I was with him and he was all over my technique. It actually was the most efficient way for me to feel stronger and it improved my posture
significantly.
And I missed him since I left California.
I have a new trainer in Philadelphia who's great, and I still deadlift occasionally with
him.
But I can say I am opposed to deadlifting callously, but if you're extremely well monitored by
an experienced personal trainer or a weightlifter,
I think it could be a greater size.
Great. I love to be wrong in this case,
because I'm a huge proponent and on the podcast,
I go on and on, I mean, there's so much data now,
point in the fact that 180 to 200 minutes of the zone two cardio
kind of jogging, cycling, swimming type behaviors, very healthy for everybody.
And we should all be doing that, at least that.
Yes, I need to as well.
And that resistance training on the order of, you know, six hard sets per muscle group per
week is really important just to offset deterioration of muscles and...
I'm learning as we go here.
Skeletal function and tendon strength, and that's just to maintain.
We're not talking about all-out sets to absolute failure, but as you point out with proper
form, so even the neurosurgeon are doing this, which I think is wonderful.
As a final question, but one that I think really, or maybe second to final question,
earlier I commented on the remarkable calm,
at least perceived calm of neurosurgeons,
it could be cause or could be effect of the training.
But it's obvious to me why one would want that trait
in their neurosurgeon.
I wouldn't want a hyperactive,
certainly not an impulsive neurosurgeon, given that't want a hyperactive, certainly not an impulsive neurosurgeon,
given that the margins of error are so, so tiny, spatial scale, and probably on the temporal
scale too.
You don't want people doing things in time that are, you know, or being spontaneous at all.
Do you think that this branch of medicine that you're in selects for people that at
least can know how to control
any kind of fluctuations in autonomic ralzo.
They can calm themselves in real time.
Here's a specific question.
When I've never operated on the human brain, although I've had the privilege of being in
the operating room and seeing this with some of our experiments with people in VR, some
remarkable thing.
I wish for everybody that would get this experience at some point, not hopefully as a patient unless they have a need, but to observe it. But what was just striking to me
is the various stereotype behaviors of the surgeon. And when I did surgeries as a graduate
student, as a postdoc in the brains of other types of animals, I would find, for instance,
that if I started to tremble a little bit, if I tapped my left foot that my hand would stabilize a bit,
that there's this kind of need to move the body,
or one feels the impulse.
Maybe that's my Tourette's like compulsions again.
But that one can kind of siphon off some of that energy
into another limb so that you could remain precise.
So are these sorts of things that I'm talking about,
are maybe entirely my imagination, but are these the sorts of things that I'm talking about? Maybe it's entirely my imagination,
but are these the sorts of things that one learns as a neurosurgeon? How to still the body and still
the mind? Do you have a meditative practice when you go into the operating room if you had a
particularly challenging morning or a poor night's sleep? Do you have tools that you use to calibrate
yourself and get yourself into the zone? I think this would be very interesting for people to get some insight into even if they don't want to be neurosurgeon.
Yeah, I completely agree and I appreciate the earlier
reference to neurosurgeons as astronauts because I've also heard, you know, as compared to cowboys before and it's a little bit less flattering.
I, you know,
always before and it's a little bit less flattering. You know, some of what we do surgically really does require a substantial amount of confidence.
And that confidence hopefully comes from years of training and experience.
You always worry that the confidence is sort of misplaced and that is problematic.
Luckily, you so rarely see that,
because our training is so rigorous, you know, we have a board of American board of
neurological surgeons that sort of allows and assesses surgeons to continue practice,
and holds us to a really high bar. I do think it tends to attract a certain personality.
In my subspecialty, as a deep brain stimulation surgeon,
we call it stereotactic and functional neurosurgery.
Some people have likened us to the neurologists with a scalpel.
We tend to be a bit more intellectual,
maybe bedside manners a little bit friendlier.
And then there's the vascular neurosurgeon
who doesn't sleep, and so they're not as friendly.
There's the spine surgeons who operate the most,
and so they're busy, busy, busy.
There are some of these kind of reputations going around,
but I agree with you, there's a sort of a common feature
of a calmness across neurosurgeons.
And there's some of my, obviously, my favorite people,
my closest friends.
And I can relate with them probably because of that.
Sort of a big picture.
They don't get sort of flustered.
They tend to be really good at figuring out
how to have quality time because we work really hard.
Our hours are significant, and so the time with our families, our friends, is less than
we would like it to be.
Obviously, that's true for people who work hard across any profession, but definitely
true for neurosurgeons.
I think that we're very good at figuring out how to make that time high quality. You know, even just texting with some of my friends that are neurosurgeons, a great friend of mine,
just became chairman of Duke and just connecting with him by text, which takes seconds, you know,
you feel we feel connected, you know. And I think that's a trait amongst neurosurgeons. We sort of know
how to cut to the chase in a way,
and prioritize our time.
It's a skill that we probably have it natively,
but it's also part of the training.
When we are interns now, there's a lot of work hour regulations
that is probably quite appropriate, by the way.
I think our hours before we're bordering
on not necessarily...
Let's just say they were not ideal for mental health
and sleep, which we know are very important components.
Certainly we had no time for meditation.
I definitely did not.
I wish I did.
Now knowing what I know about meditation,
my wife's a health coach, I get it, I see it,
I practice it myself with her. I see the value,
I wish I had that tool when I was in training because it's stressful. Even with the work-hour
restrictions, we still don't sleep very much. We're still at work a lot about 80 hours, you know,
a week throughout the entire career. There are times when it's more because after training,
there's no work hour restrictions.
So sometimes I feel like as faculty, we could have
used, and the trainees are a little bit more protected now.
It definitely was the reverse at one point.
That's also a huge problem, probably more of a problem.
And I'm joking a little bit, I don't necessarily think we're abused,
but certainly our hours are significant.
But they come a bit more here and there.
On my OR days when I'm operating, those are long days.
But on the days that I'm lucky enough to be a researcher, like you those days tend to
be a bit gentler unless I'm grandriding.
Those days can be long as you know.
So a day has to question, I do think we're self-selected for it, but I also think it's part of the training.
You know, we, because of the long hours that we're in the hospital, we're taking care of sick patients,
and we have sort of a type A mentor approach where our mentors are hard on us.
You know, we learn to cope with our stress and be efficient and prioritize things
despite the stress of it all.
And I think, you know, we take from that this sort of calm demeanor.
And you know, perhaps, perhaps it's just amplifies what we were probably drawn to.
Because before we come to neurosurgery, we might rotate in neurosurgery.
We might spend a month, you know, pretending to be a neurosurgeon, learning from residents and faculty
that are practicing the specialty.
But prior to actually starting your training,
you never experience anything like being
a resident neurosurgery of the stress
and the volume of patients that you have to take care of
and the long nights.
It can be quite lonely, by the way.
You develop friends in the hospital, but sometimes you're on your own when you're on call,
and you have backup, you can call your chief resident or your attending, but you really
have to learn how to take care of patients yourself.
You obviously form teams with nurses and staff and things like that, and other residents,
but it can be lonely, it can be really challenging.
And I think because of those experiences that all neurosurgeons go through,
we tend to have this sort of unflappable personality
that perhaps we started with a bit
compared to the average person
but the training definitely amplifies it.
And do you have tools that you implement
if you ever feel that you're getting slightly off center?
I do now. When I was in training, I actually remember in my second year. So most neurosurgery
programs when you're a junior resident, in some ways that's your toughest year, not in every way.
It is your toughest year because it's your young and your inexperienced. And you don't know what you don't know.
And that's why it's such a tough year because you have to learn a lot very quickly.
For patient safety reasons, for self-survival, you just have to learn a lot.
And you're all called by yourself in the hospital.
And it's a real challenge.
And I think that, you know, I, you know, personally,
I gained a lot of weight during that year.
The only exercise I did consciously was taking the stairs.
I refused to take the elevator.
And I was at Penn at Hup, where I currently practice now.
And I remember I would see patients anywhere
from sort of the ground floor, where the trauma bay was,
or the ER, all the way up to Founders 12th, the 12th floor, and I would never take
an elevator.
That was my rule for the year because I knew I would not have time to exercise, but I
would just take the stairs.
And in the beginning of the year, I would be a little winded when I got to the 12th floor.
But by the end of the year, actually, it didn't really phase me.
It became a great habit to have.
The problem with that, though, was I paired that, unfortunately,
with a lot of sleepless nights, or not enough sleepless, say. And I had this terrible habit
of drinking coffee late at night, and I would put a lot of sugar in it. And it was sort
of the only way for me to get a quick, you know, a quick bout of energy that, for some
reason, I prioritized at that time,
obviously knowing that I would crash, which I always did, and I always kind of regretted
it, but I still did it anyway.
And I attribute that to poor decision making, inexperience, and perhaps being a little vulnerable,
like I think we all are.
That's why I relate with a lot of the research that I do.
And I remember I got married in my third year, the year after my second year. And my wife and I are my fiance at the time. We started going to the gym together
in the morning. And my hours were a little better. So I would actually be able to exercise before
I operated that day. And I operated almost every day as a third year resident. So I remember
I'd get to the gym really early. And in three months I lost like 20 pounds. And I wasn't trying to
lose weight. I just was sleeping better and taking care of myself.
And I remember when we got married,
I fit into a tuxedo that I had in college
or I would have fit me in college.
It actually wasn't a tuxedo admittedly,
but it was the same size as my tuxedo from college.
So I think that I've always related with the problems
that our patients have to a certain extent.
And when I've been most vulnerable,
which is when I was working the hardest
with the least amount of sleep, I related with it the most.
And yes, exercise for me has always been my tool.
More recently, exercise, some strength training,
I think is important, compared with cardio.
I don't do enough of either, but I definitely do some, and that helps I'm not going to do it. I'm not going to do it. I'm not going to do it. I'm not going to do it.
I'm not going to do it.
I'm not going to do it.
I'm not going to do it.
I'm not going to do it.
I'm not going to do it.
I'm not going to do it.
I'm not going to do it.
I'm not going to do it.
I'm not going to do it.
I'm not going to do it.
I'm not going to do it.
I'm not going to do it.
I'm not going to do it.
I'm not going to do it.
I'm not going to do it.
I'm not going to do it.
I'm not going to do it.
I'm not going to do it.
I'm not going to do it.
I'm not going to do it. I'm not going to do it. I'm not going to do it. I'm not going to do it. I'm forward to it every night. And sometimes my wife falls asleep
and I come to bed a little later and I whisper, I'm like, okay, if I turn the app on, so
she does the same to me because I think we both value it. I think that's been very helpful.
And I didn't have that tool, probably when I needed it most, but I have it now and it's
very helpful.
I really appreciate you sharing those tools at a number of people. I'm guessing out there might want to become neurosurgeons.
I really believe that in hearing today's conversation that you will spark an interest in medicine
and or neurosurgery.
I hope so.
Well, certainly you need to be a physician before you can become a neurosurgeon.
So end neurosurgery in some cases, and that would be beautiful.
And I predict that will happen.
That will happen.
Excuse me, as a consequence of what you've shared today.
I really appreciate your mentioning of the emphasis and appreciation on quality time.
I very much see this as quality time.
I know that our listeners will as well.
I really want to thank you for taking time out of your not just immensely busy but very
important schedule because, again,
the work that you're doing is really out there on that cutting, I don't want to say bleeding
edge because in this context it's not going to sound right.
But on that extreme cutting edge of what we understand about how the human brain works
and how it can be repaired, they're doing marvelous work.
We will point people to various places they can find you online and should they need the
help of your clinic to your clinic and your laboratory as well.
On behalf of everybody and myself as well, thank you so, so very much.
I'm honored.
Thank you so much for having me.
Thank you for joining me today for my discussion with Dr. Casey Halpern about the use of deep
brain stimulation and novel technologies for the treatment of
eating disorders and movement disorders of various kinds.
For those of you that are interested in learning more about Dr. Halpern's research, please
see the links in our show note captions that include links to his laboratory website and to his
clinic, as well as various research publications that are available in complete form as downloadable
PDFs.
If you're learning from and are enjoying this podcast,
please subscribe to our YouTube channel.
That's a terrific zero cost way to support us.
In addition, please subscribe to the podcast
on both Spotify and Apple.
And on both Spotify and Apple,
you can leave us up to a five-star review.
If you have questions for us or comments
or feedback of any kind,
please put that in the comment section on YouTube.
We do read all the comments.
Please also check out the sponsors mentioned at the beginning of today's episode.
That's the best way to support this podcast.
Not so much today, but in many previous episodes of the Huberman Lab podcast, we talk about
supplements.
While supplements aren't necessary for everybody, many people derive tremendous benefit from them
for things like enhancing sleep and focus and hormone optimization.
The Huberman Lab podcast has partnered with Momentus Supplements.
If you'd like to see the supplements of the Huberman Lab podcast
that's partnered with Momentus on,
you can go to live momentus spelled O-U-S,
so livemomentus.com slash Huberman.
And there you'll see a number of the supplements
that we talk about regularly on the podcast.
I should just mention that that catalog of supplements
is constantly being updated.
If you haven't already signed up for the neural network newsletter,
this is a monthly Huberman Lab podcast newsletter
in which you get some brief show note summaries
as well as a lot of actionable tools in summary form.
Many people find these very useful
for distilling out the vast amount of information
that we cover on the podcast.
So for instance, if you go to HubermanLab.com,
you can click on the menu,
click to Neural Network newsletter or simply newsletter, and you can sign up, just give us your email.
We do not share your email with anybody, and again, it's completely zero cost.
We also have examples of previous newsletters that you can download immediately without having to sign up for anything and decide whether or not you want to sign up.
Again, that's the Neural Network newsletter at HubermanLab.com.
If you're not already following us on social media, we are HubermanLab on Instagram, on Twitter,
on Facebook, and on LinkedIn.
And especially on Instagram, and on Twitter,
I cover many of the tools that are discussed
on the HubermanLab podcast,
but also a lot of science and science-based tools
not covered on the HubermanLab podcast.
Again, it's HubermanLab on all platforms.
Once again, thank you for joining me today
for my discussion with Dr. Casey Halpern.
I hope you learned as much as I did. And as always, thank you for your interest in science.