Essentials: Compulsive Behaviors & Deep Brain Stimulation | Dr. Casey Halpern

Welcome to Huberman Lab Essentials, where we revisit past episodes for the most potent and actionable science-based tools for mental health, physical health, and performance. I'm Andrew Huberman and I'm a professor of neurobiology and ophthalmology at Stanford School of Medicine. And now for my discussion with Dr. Casey Halpern. Casey, I should say, Dr. Halpern. Welcome.

Thank you. a neurosurgeon, which I consider the astronauts of neuroscience. For those that aren't familiar with the differences between neurosurgery, neurology, psychiatry, maybe you could just educate us a bit, what does a neurosurgeon do? And how do you think about and conceptualize the brain? Yeah, the scope of neurosurgery is quite broad. We take out brain tumors, we clip aneurysms in the brain, we take care of patients that have had traumatic brain injury, um concussion, uh spine surgery.

ninety percent of what neurosurgeons do around the country, uh, you know, taking care of herniated discs and lumbar fusions. So you know the the scope is The entire central nervous system, incl including the peripheral nervous system, we take care of patients with carpal tunnel syndrome and nerve disorders. 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 uh chief of stereotectic and functional neurosurgery. All I do is deep brain stimulation surgery and a complement to that is focus ultrasound or transcranial. focus ultrasound, which is a non invasive way to do an ablation in the brain, recently F D A approved, and it's F D A approved for tremor at the moment. Deep brain stimulation is a procedure where we have to place a

uh a very thin wire that's insulated deep into uh a part of the brain that's involved in Parkinson's disease, for example. Uh 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 contacts at the bottom of the wire. They're very small. It's a bit more like I have to implant a a tool to to deliver you a medication.

uh but that medication is gonna be in the form of electricity and it's gonna be delivered into a very small region of the brain. I'm very privileged to be able to interact with the human brain in this way. It's always in the m i 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 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 um, not just for movement disorders like Parkinson's disease, but for example, patients with Parkinson's disease that have

uh a psychiatric uh uh comorbidity like depression or obsessive compulsive disorder. A lot of these patients are highly compulsive, uh uh and impulsive. Um 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 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 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 when we have a patient with tremor who has been tremoring for the past twenty years, if we can deliver stimulation through that electrode in the clinic, we have 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 another kind of symptoms.

I'd love to learn more from you 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? 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.

Uh 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. Uh I'm very focused on trying to improve outcomes of deep brain stimulation for for OCD. So I I do feel I have expertise and and a perspective to share. I do feel that as a neurosurgeon I am obligated to better understand

where the obsessions in the brain come from and how we can interrupt them to stop the compulsion that's associated with the obsession better than we're actually doing it. I've been uh 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, uh 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 O C D uh at a broader level as well. I consider OCD to be a a spectrum disorder in a way. Uh and I I I apologize to those who who might feel that I'm using that term incorrectly. I I'm using it

patients that have obsessions and even some related compulsions might not meet criteria for O C D. As a neurosurgeon, I'm really obsessive about safety and compulsive about my surgical procedures. So You know, I I think that some aspect of O C D which we often joke about, but we should, you know, consider seriously,'cause people do suffer from this. uh some aspect of it helps us. Uh there are, you know, famous uh CEOs that probably have some level of O C D, uh surgeons and scientists alike. So

Uh perhaps if it can be controlled, it's an asset. And uh but if it goes awry and is uncontrollable then it becomes obsessive compulsive disorder. And Uh 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. Well SSRIs are sort of the the first.

uh line for O C D but also tricyclics can be helpful. So this is still the serotonin system. Um but as we know the serotonin system interacts with the you know neurogenergic uh system and the dopamine system. So it's hard to um Uh 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 whole clinic at my institution, um uh focused it was started by Ed Nafoa. Um This is what they do for these patients, uh, is offer 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.

uh compulsions to help these patients live in everyday and and function. fabulously helpful pa uh therapies for a variety of patients, but there's still about thirty percent of patients that still suffer from O C D and some of them have severe O C D, sometimes it's moderate to severe. And those are the patients that I'm really

motivated to try to help. Um, our therapies for those patients right now, uh, I would say are are worth pursuing, but not optimal. Um, and so it's 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 capsulotomy, 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. Um others would say it's safer to modulate. I have seen uh patients do very well with these ablations. And so

You know, you asked me earlier what 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 uh traverse parts of the brain without having any adverse effects on patients um function, at least that you can test.

Um 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.

Uh but nonetheless, despite how safe they might be, uh, 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 we can generally um uh achieve a responder rate of about fifty percent. Um and responders still have symptomatic O C D. So I'm really uh uh sort of inspired to uh really find a way to deliver these therapies in a more disease specific or symptom specific way.

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come into your clinic this, you know, for this sort of uh work of ablations or stimulation, uh, where would you first start to probe in the brain? Yeah, you this is a uh a disorder of both cortex and the sub subcortex. We find that areas in the cortex like the prefrontal and orbital frontal cortex are are not functioning they w the way they would in a non-OCD patient. They are often hyper

functioning and we need to find a way to try to normalize their function. And then there are projections to the subcortex. This is the basal ganglia, like caudaputamin, or the dorsal stratum, and these are interconnected with the ventral stratum. This is an area of the brain that I uh focus a lot of my energy in. Um this is the ventral stratum, which is not limited to but includes the nucleus accumbens. This is an area of the brain that

Uh, we know to be involved in gating reward seeking behavior. When it's perturbed it seems to gate compulsive behavior, meaning a rat will pursue a reward despite punishment, despite a foot shock, for example. And that can be similar to an O C D patient. They will check their home for safety. uh until three AM in the morning and not sleep that night, doing something because of the urge, but despite the risk. When our judgment is consistently uh sort of puts us at risk, that's where

we have something like O C D contamination behavior where they if they feel contaminated, they'll wash their hands for hours repeatedly, or if they drop their toothbrush on the floor. Th this will lead to a compulsive behavior of cleaning a toothbrush or brushing your teeth consistently. Very, very common symptoms that we see, uh or signs that that patients report to us or or that we observe. But you know, patients with eating disorders, you know, they tend to

If if they have benige disorder, they'll overeat. If they have bulimia, they might purge despite the risk of these things. And so um addiction is is similar. We we tend to drug seek if we're addicted. Um uh we'll we'll pay off a a dealer uh in order to get our fix and despite the risk and

And that type of urge despite the risk is something that I I've always been really interested in. And 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. And I think the nucleus cumbins and the cortical areas that we've been discussing that that sort of send projections to these areas are are probably at least one of the main circuits involved in these kinds of things.

What is nucleus accumbens 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. It has a lot of functions. Uh it it interconnects with many parts of the brain. So when I started getting interested in reward and what a 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 that's a normal phenomenon. That that's not something we're trying to stop. The the issue is if you have an urge for rew a reward that either puts you or somebody else at risk, it's probably a reward we shouldn't have. If you're a drug addict and you uh use heroin or opiate, 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. If you have O C D and you

can't sleep at night because you're so nervous that you didn't lock the door and you've checked thirty times. That's an urge we gotta treat. Eating disorder is the same. This problem can be ameliorated or improved upon by a better understanding and a tailored treatment to the nucleus accumbents specifically. It seems that repeated exposure to something like a drug of abuse or any type of reward

that is a really strong reward. In a way it it can hijack normal functioning of the nucleus accumbens. So the goal is to just disrupt perhaps what is kind of habitual. Um or or at least this kind of recurring problem that is happening. You know, people that have binge eating disorder, at least at a severe level, they tend to bitch about once a day.

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, these 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, uh 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 handshaking. Продолжение следует...

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 uh 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 we are very confident that when we stimulate that area of, in this case, the subphalamic nucleus, we will disrupt that tremor circuit and that tremor will dissolve. And it does. So what is the um analogue to tremor in terms of appetite and desire to Binge. So craving is a term That, you know, there's probably other terms we could use, by the way, but that 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. Um 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. Um So uh but the word craving is relatable. And so we set out to see if we could identify craving cells. Um in a patient with OCD, which is related, in fact we target a very similar part of the brain, uh we try to identify

cells related to obsessions. And we believe we did do that. It was a single case study, uh, where we tried to optimize where our electrode would 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 in human trials where

Um we're trying we're trying to establish where in the brain we need to be. Uh I think this type of approach is really critical.

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What is the status of non invasive brain stimulation, ablation, and blocking activity in the brain? My understanding is that transcranial magnetic stimulation is being used to treat depression and a number of other um brain syndromes. Uh non invasively, so no no drilling through the skull. My understanding is that the spatial precision isn't that great. Um

ultrasound is something I hear a lot about these days. Um, and my understanding is that ultrasound can allow researchers and clinicians to stimulate specific brain areas. What are your thoughts on these forms of non-invasive Meaning no no flipping open of a piece of the skull type brain stimulation and blockade of brain activity. We need to embrace non-invasive approaches. Some of them are a little fluffy in that we don't understand how they work.

we don't necessarily understand how deep brain stimulation works, by the way. So 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. TMS, transcranial magnetic stimulation.

It is FDA approved for depression, by the way. It's also FDA approved for OCD and for nicotine addiction. We believe we can use TMS to to define a circuit that, if modulated, improves OCD, albeit temporarily. And in those patients, if it's temporary, they would be appropriate for an invasive study.

So um 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. Um but um I think we can help make them more precise and to probe non invasively with purpose. Perhaps one day there will be a TMS target for anorexia and obesity. Uh If we are scratching the surface with invasive approaches to these problems.

we we're even doing less with the brain stimulation. Um so we have so much work to do there. Eating disorders and TMS have been so um sort of uh scarcely studied or or s there have been s such little research done in that space. And so it it it is an area that we need to to work on. So ultrasound right now Transcranial magnetic guide m magnetic resonance guided focus ultrasound. So um uh this this is an FDA approved method to Deliver an ablation to the brain non invasive.

There are uh 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. Um there are trials um 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 uh area, uh perhaps for a brain tumor or something like that. So um it's a very exciting field. Um and it is FDA approved for tremor right now. And so I actually do it routinely. Um for patients with uh tremor with Parkinson's or essential tremor. And so um I I love doing it. It's uh 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 a similar result. It's fabulously effective for these patients. It treats patients on one side, usually their dominant hand or their worst hand, and it um 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? Uh well, um perhaps uh actually that would be the ideal. The problem is we don't know where to do the ablation. Um there is a trial that we would like to do for O C D 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 O C D and it helps a bit. That's called a capsulotomy.

But really the outcome is probably going to be about the same. It's a nice method because it's it's non-invasive, but we need to find a new target for these, for these conditions. And because of the common denominator of the urge despite the risk. sort of that compulsion. Um yeah, perhaps it could be the same target. I don't know. Um but I would argue we need to do these modulatory experiments either with a device or with uh invasive recordings uh to better understand where these

problems are coming from to define where we should do an ultrasound treatment. There has been a revolution in America, it was in Europe before it was in America, where we would do stereo encephalography. Which is basically like doing an EEG of patients with epilepsy, but with 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 um you know, we could stimulate those electrodes to see if there was a symptom that was important and uh try to identify a a region that we thought we could either remove surgically a a blade with a laser or put a 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, um, but the uh 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 uh 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 compuls compulsive disorder. We're awaiting an FDA decision on that. Uh but actually I credit uh uh our colleagues at Baylor and at UCSF for for studying this uh already. 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. Um 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. Uh but actually after a large volume of uh cases perhaps.

they could pool that data to develop a a new ultrasound target for depression. I think that would be fabulous and probably is their long term goal. Not to speak for them, uh, but that would be something that I I'm sure is on their radar. You might ask, well why aren't you doing this for obesity right now in uh in our in our study? And the reason is that um we've developed a target for obesity uh and binge eating disorder uh developed out of mice.

that we believe um is relevant for the human state because you can model this problem in a mouse a bit better than y than you can model depression or O C D.

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 state or study epileptics that have comorbid depression, for example.

Uh and that can really validate this approach as well. But in the end, it's it's getting into the human brain that we need to do in the disease.

specifically um that will eventually lead to a non-invasive approach, uh either a lesion or modulatory approach. Modulatory would be like TMS or lesion approach would be with uh ultra Perhaps one of the most underestimated but powerful tools to improve your mental health, your physical performance, and your cognitive performance is ensuring you get enough hydration every day.

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Again, that's Rora R O R R A dot com slash Huberman. If people can be made to feel or make themselves feel just a little bit better, a little less anxious just prior to a craving episode or a binge episode.

And 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 even veering towards suicidal. Thinking. Seems like that awareness seems like maybe among the best tools that people could develop. 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. And 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'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 to try to provoke this electrographic, electrical signal um 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 s to see can this device detect this craving cell signal? Which is gonna 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. Um so they're they're only hearing or or detecting, I should say, thousands of cells responses. We actually have a way to provoke

binges. It's called a mood provocation. It's very well well very well validated. It's a little bit like provoking seizures in the epilepsy monitoring unit, but here in these sort of uh Psychiatric monitoring unit or the the food monitoring unit. Uh we we actually have a psychiatrist and eating disorder specialist come and induce a mood that is related to each patient's sort of self described binge episode. So the psychiatrist comes in and provokes. Yes. 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. Um the patients all wear an eye tracker 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 through a one day 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 uh 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. Um the problem with cognitive behavioral therapy, or I should say the limitation of it, I actually don't have a any problem with it. I think it's a wonderful treatment. Um

is that if you stop it, many of these patients go back to their old behaviors. I don't want to say old habits, but it it might be a habit, but the old behavior. And so um that's the problem is that 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. Um

But I think in in in in the less severe patients, improving awareness is key. But in these really refractory patients, this is this is kind of like this is the disease, despite the awareness, they can't control them. 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 uh artificial intelligence here? Uh there are a couple of laboratories up at the University of Washington that are using particular signature patterns of within voice to try and help suicidal uh 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. Um

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, et cetera, integrating a a huge number of cues and then signaling somebody with a uh you know a yellow light. Like, you know, you're headed into a depressive episode and the person might say, Oh, I feel fine or I feel pretty good. This is kind of baseline state for me and they say, Uh uh, 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. Yep. Um, 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. Um 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 uh 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. i immensely a focus of the lab is impulsivity. We've talked mostly about compulsion, compulsion being, you know, going after a reward or or the urge despite the risk. Um

Impulsivity is is similar, but different. It's it's kind of going after something um a little bit if you if you model impulsivity in a r in a mouse, it's you know related to you know, going after a a food reward without the sort of paired tone that your the mouse is supposed to wait for. The mouse doesn't want to wait anymore. They they just go after the food. Um I've been that mouse.

Yeah, we all we can all relate with this, uh, to a certain extent. Again, it's a spectrum. So um So in any case I uh non sequitur, but I I 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 we're just scratching the surface, but um

These are the kinds of solutions we need. Some of these problems are of epidemic proportions. Largest public health problems in this country, in this world: obesity, opiate crisis, depression.

Suicidality. I mean, that's like a third of our country, maybe more. We need scalable solutions. But you know, I'm I'm a neurosurgeon. I'm only gonna be able to treat the most severe of patients with these problems. You know, how You know, we've only done about 200,000 deep brain stimulation surgeries ever. So I mean the problem we're talking about here is fifty 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 a you know, some sort of wearable fancy tool that, you know waste people's money and time. You know, we need real therapies for these things. Not that w these devices that we're discussing are not. Uh I think actually there's lots of promise.

And we use machine learning in the lab all the time. I'm not a uh an electrical engineer or the computational neuroscientist doing this type of work. I I just help develop the hypotheses around it, but um and help fundraise around it. But I I definitely think there's a a future for it. I just I I suspect we're we're scratching the surface on how best to do it.

I really appreciate you sharing uh those tools. A a number of people, uh I'm guessing out there might wanna 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. Um 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 be happen that will happen, excuse me, as a consequence of

what you've shared today. Really wanna 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 uh 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. So on behalf of everybody and and myself as well, thank you so, so very much.

Honored. Thank you so much for having me.