Huberman Lab - How to Improve at Learning Using Neuroscience & AI | Dr. Terry Sejnowski
Episode Date: November 18, 2024In this episode, my guest is Dr. Terry Sejnowski, Ph.D., professor of computational neurobiology at the Salk Institute for Biological Studies. He is world-renowned for exploring how our brain processe...s and stores information and, with that understanding, for developing tools that enable us to markedly improve our ability to learn all types of information and skills. We discuss how to learn most effectively in order to truly master a subject or skill. Dr. Sejnowski explains how to use AI tools to forage for new information, generate ideas, predict the future, and assist in analyzing health data and making health-related decisions. We also explore non-AI strategies to enhance learning and creativity, including how specific types of exercise can improve mitochondrial function and cognitive performance. Listeners will gain insights into how computational methods and AI are transforming our understanding of brain function, learning, and memory, as well as the emerging roles of these tools in addressing personal health and treating brain diseases such as Alzheimer’s and Parkinson’s. Access the full show notes for this episode at hubermanlab.com. Pre-order Andrew's new book, Protocols: protocolsbook.com Thank you to our sponsors AG1: https://drinkag1.com/huberman BetterHelp: https://betterhelp.com/huberman Helix Sleep: https://helixsleep.com/huberman David Protein: https://davidprotein.com/huberman LMNT: https://drinklmnt.com/huberman Joovv: https://joovv.com/huberman Timestamps 00:00:00 Dr. Terry Sejnowski 00:02:32 Sponsors: BetterHelp & Helix Sleep 00:05:19 Brain Structure & Function, Algorithmic Level 00:11:49 Basal Ganglia; Learning & Value Function 00:15:23 Value Function, Reward & Punishment 00:19:14 Cognitive vs. Procedural Learning, Active Learning, AI 00:25:56 Learning & Brain Storage 00:30:08 Traveling Waves, Sleep Spindles, Memory 00:32:08 Sponsors: AG1 & David 00:34:57 Tool: Increase Sleep Spindles; Memory, Ambien; Prescription Drugs 00:42:02 Psilocybin, Brain Connectivity 00:45:58 Tool: ‘Learning How to Learn’ Course 00:49:36 Learning, Generational Differences, Technology, Social Media 00:58:37 Sponsors: LMNT & Joovv 01:01:06 Draining Experiences, AI & Social Media 01:06:52 Vigor & Aging, Continued Learning, Tool: Exercise & Mitochondrial Function 01:12:17 Tool: Cognitive Velocity; Quick Stressors, Mitochondria 01:16:58 AI, Imagined Futures, Possibilities 01:27:14 AI & Mapping Potential Options, Schizophrenia 01:30:56 Schizophrenia, Ketamine, Depression 01:36:15 AI, “Idea Pump,” Analyzing Research 01:42:11 AI, Medicine & Diagnostic Tool; Predicting Outcomes 01:50:04 Parkinson’s Disease; Cognitive Velocity & Variables; Amphetamines 01:59:49 Free Will; Large Language Model (LLM), Personalities & Learning 02:12:40 Tool: Idea Generation, Mind Wandering, Learning 02:18:18 Dreams, Unconscious, Types of Dreams 02:22:56 Future Projects, Brain & Self-Attention 02:31:39 Zero-Cost Support, YouTube, Spotify & Apple Follow & Reviews, Sponsors, YouTube Feedback, Protocols Book, Social Media, Neural Network Newsletter Disclaimer & Disclosures Learn more about your ad choices. Visit megaphone.fm/adchoices
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Welcome to the Huberman Lab podcast, where we discuss science and science-based tools for everyday life.
I'm Andrew Huberman, and I'm a professor of neurobiology and ophthalmology at Stanford School of Medicine.
My guest today is Dr. Terry Signowski.
Dr. Terry Signowski is a professor at the Salk Institute for Biological Studies, where he directs the Computational Neurobiology Laboratory.
And as his title suggests, he is a computational neuroscientist.
That is, he uses math as well as artificial intelligence and computing methods to understand
this overarching, ultra-important question of how the brain works.
Now, I realize that when people hear terms like computational neuroscience, algorithms,
large language models, and AI, that it can be a bit overwhelming and even intimidating.
But I assure you that the purpose of Dr. Sagnowski's work, and indeed today's discussion,
is all about using those methods to clarify how the brain works and indeed to simplify the
answer to that question.
So for instance, today you will learn that regardless of who you are, regardless of your experience,
that all your motivation in all domains of life is governed by a simple algorithm or equation.
Dr. Signowski explains how a single rule, a single learning rule, drives all of our motivation-related
behaviors.
And it of course relates to the neuromodulator dopamine.
And if you're familiar with dopamine as a term, today you will really understand how dopamine
works to drive your levels of motivation or, in some cases, lack of motivation and how to
overcome that lack of motivation.
Today we also discuss how best to learn.
Dr. Szyndowski shares not just information about how the brain works, but also practical tools
that he and colleagues have developed, including a zero-cost online portal that teaches
you how to learn better based on your particular learning style, the way that you in particular
forge for information and implement that information.
Dr. Sagnowski also explains how he himself uses physical exercise
of a particular type in order to enhance his cognition,
that is his brain's ability to learn information
and to come up with new ideas.
Today we also discuss both the healthy brain
and the diseased brain in conditions like Parkinson's
and Alzheimer's and how particular tools that relate
to mitochondrial function can perhaps be used
in order to treat various diseases,
including Alzheimer's dementia.
I'm certain that by the end of today's episode,
you will have learned
a tremendous amount of new knowledge about how your brain works and practical tools that you can
implement in your daily life. 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 BetterHelp. BetterHelp offers professional therapy with a licensed therapist
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I've been doing weekly therapy for well over 30 years.
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And now for my discussion with Dr. Terry Sainowski.
Dr. Terry Sainowski.
Welcome.
Great to be here.
We go way back, and I'm a huge, huge fan of your work because you've worked on a great many different things in the field of neuroscience.
You're considered by many a computational neuroscience, so you bring mathematical models to an understanding of the brain and neural networks.
And we're also going to talk about AI today, and we're going to make it accessible for everybody, biologist or no, math background or no.
To kick things off, I want to understand something.
I understand a bit about the parts list of the brain,
and most listeners of this podcast will understand a little bit of the parts list of the brain,
even if they've never heard an episode of this podcast before,
because they understand there are cells, those cells are neurons,
those neurons connect to one another in very specific ways that allows to see, to hear, to think, etc.
But I've come to the belief that even if we know the parts list,
it doesn't really inform us how the brain works.
This is the big question.
How does the brain work?
what is consciousness, all of this stuff.
So where and how does an understanding of how neurons talk to one another start to give us a real
understanding about like how the brain works?
Like what is this piece of meat in our heads?
Because it can't just be, okay, the hippocampus remembers stuff and the, you know, the visual cortex
perceives stuff.
When you sit back and you remove the math from the mental conversation, if that's possible
for you.
how do you think about, quote, unquote, how the brain works?
Like, at a very basic level, what is this piece of meat in our heads really trying to accomplish?
From let's just say the time when we first wake up in the morning and we're a little groggy
till we make it to that first cup of coffee or water, or maybe even just to urinate first thing in the morning.
What is going on in there.
What a great question.
And, you know, I have a,
Pat Churchland and I wrote a book, Computational Brain,
and in it there's this levels diagram.
And it levels of investigation at different spatial scales
from the molecular at the very bottom to synapses and neurons,
circuits, neural circuits, how they're connected with each other,
and then brain areas in the cortex and then the whole central nervous system
span 10 orders of magnitude, you know, 10 to the 10.
in spatial scale. So, you know, where is consciousness in all of that? So there are two approaches
that neuroscientists have taken. I shouldn't say neuroscientists. I should say that scientists
had taken. And the one you describe, which is, you know, let's look at all the parts. That's the
bottom up approach. You know, take it apart and just a reductionist approach. And you make a lot of progress.
You can figure out how things are connected and understand how development works, how neurons connect.
But it's very difficult to really make progress because quickly you get lost in the forest.
Now, the other approach, which has been successful, but at the end on satisfying, is the top-down approach.
And this is the approach that psychologists have taken looking at behavior and trying to understand
the laws of behavior, this is the behaviorist.
But even people in AI were trying to do it top-down to write programs
that could replicate human behavior, intelligent behavior.
And I have to say that both of those approaches, bottom-up or top-down,
have really not gotten to the core of answering any of those questions, the big questions.
But there's a whole new approach now that is emerging.
in both neuroscience and AI at exactly the same time.
At this moment in history, it's really quite remarkable.
So there's an intermediate level between the implementation level at the bottom,
how you implement some particular mechanism.
And the actual behavior of the whole system is called the algorithmic level.
It's in between.
So algorithms are like recipes.
They're like, you know, when you bake a cake, you have to have ingredients and you have to say
the order in which they're put together and how long.
And, you know, if you get it wrong, you know, it doesn't work.
You know, it's just a mess.
Now, it turns out that we're discovering algorithms.
We've made a lot of progress with understanding the algorithms that are used in neural circuits.
and this speaks to the computational level of how to understand, you know, the function of the neural
circuit.
But I'm going to give you one example of an algorithm, which is one we worked on back in the
1990s when Peter Deanne and Reed Montague were post-oxone lab.
And it had to do with a part of the brain below the cortex called the basal ganglia, which is a
responsible for learning sequences of actions in order to achieve some goal. For example, if you want to
play tennis, you know, you have to be able to coordinate many muscles and a whole sequence of
actions has to be made if you want to be able to serve accurately, and you have to practice,
practice, practice. Well, what's going on there is that the basal ganglia basically is taking over
from the cortex and producing actions that get better and better and better and better.
And that's true not just of the muscles, but it's also true of thinking.
If you want to become good in any area, if you want to become a good financier,
if you want to become a good doctor or a neuroscientist, right,
you have to be practicing, practicing, practicing, practicing in terms of understanding
what's the details of the profession and what works, what doesn't work, and so forth.
And it turns out that this basal ganglia interacts with the cortex, not just in the back, which is the action part, but also with the prefrontal cortex, which is the thinking part.
Can I ask you a question about this briefly? The basal ganglia, as I understand are involved in the organization of two major types of behaviors, go, meaning to actually perform a behavior.
But the basal ganglia also instruct no go. Don't engage in that behavior. And learning an expert golf swing or,
or even a basic golf swing or tennis racket swing involves both of those things,
go and no go.
Given what you just said, which is that the basal ganglia are also involved in generating
thoughts of particular kinds, I wonder, therefore, if it's also involved in suppression
of thoughts of particular kinds.
I mean, you don't want your surgeon cutting into a particular region and just thinking about
their motor behaviors, what to do and what not to do.
they presumably need to think about what to think about, but also what to not think about. You don't want that
surgeon thinking about how their kid was a brat that morning, and they're frustrated because the two things interact. So is there go, no go in terms of action and learning, and is there go no go in terms of thinking?
Well, I mentioned the prefrontal cortex and that part, the loop with the basal ganglia, that is one of the last to mature in early adulthood.
And, you know, the problem is that for adolescence, it's not the no-go part for, you know, planning and actions isn't quite there yet.
And so often it doesn't kick in to prevent you from doing things that are not in your best interest.
So, yes, absolutely right.
But one of the things, though, is that learning is involved.
And this is really a problem that we cracked first theoretically in the 90s and then experimentally later by requirements.
from neurons and also brain imaging in humans.
So it turns out we know the algorithm that is used in the brain
for how to learn sequences of actions to achieve a goal.
And it's the simplest possible algorithm you can imagine.
It's simply to predict the next reward you're going to get.
If I do an action, will it give me something of value?
and you learn every time you try something, whether you got the amount of reward you expect it or less,
you use that to update the synapses, synaptic plasticity, so that the next time you'll have a better chance of getting a better reward,
and you build up what's called a value function.
So the cortex now over your lifetime is building up a lot of knowledge about things that are good for you,
things that are bad for you, like you go to a restaurant, you order something, how do you know what's going to
for you, right? You've had lots of meals and a lot of places, and now that is part of your value function.
This is the same algorithm that was used by AlphaGo. This is the program that DeepMine built.
This is an AI program that beat the world Go champion. And Go is the most complex game that humans
have ever played on a regular basis.
Far more complex than chess, as I understand. Yeah, that's right. So Go,
is to chess, which has to something like checkers. In other words, the level of difficulty is
another way off above it because you have to think in terms of battles going on all over the
place at the same time. And the order in which you put the pieces down are going to affect
what's going to happen in the future. So this value function is super interesting. And I wonder
whether, and I think you answer this, but I wonder whether this value function is implemented
over long periods of time. So you talked about the value function in terms of learning a motor
skill. Let's say swinging a tennis racket to do a perfect tennis serve or even just a decent
tennis serve. When somebody goes back to the court, let's say on the weekend, once a month
over the course of years.
Are they able to tap into that same value function every time they go back, even though
there's been a lot of intervening time and learning?
That's question number one.
And then the other question is, do you think that this value function is also being played
out in more complex scenarios, not just motor learning, such as, let's say, a domain of life
that for many people involve some trial and error would be like human relationships.
We learn how to be friends with people.
We learn how to be a good sibling.
We learn how to be a good romantic partner.
We get some things right.
We get something's wrong.
So is the same value function being implemented?
We're paying attention to what was rewarding.
But what I didn't hear you say also was what was punishing.
So are we only paying attention to what is rewarding?
Or we're also integrating punishment.
We don't get an electric shock when we get the serve wrong, but we can be frustrated.
What you identified is some very important feature.
feature, which is that rewards, by the way, you know, every time you do something, you're
updating this value function every time.
And it accumulates.
And the answer to your first question, the answer is that it's always going to be there.
It doesn't matter.
It's a very permanent part of your experience and who you are.
And interestingly, and behaviors knew this back in the 1950s, that you know.
you can get there two ways of trial and error.
You know, small rewards are good because you're constantly coming closer and closer to
getting what you're seeking, better tennis player or being able to make a friend.
But the negative punishment is much more effective.
One trial learning.
You don't need to have...
you know, a hundred trials to, you know, what you need, you know, when you're training a rat
to do some task with small food rewards. But if you just shock the rat, boy, that rat
doesn't forget that. Yeah, one really bad relationship will have you learning certain things
forever. And this is also PTSD, post-traumatic stress disorder, is another good example of that.
That can screw you up for the rest of your life. So, so, but the other thing, and you pointed out
something really important, which is that a large part of the prefrontal cortex is devoted to
social interactions. And this is how humans, you know, when you come into the world, you don't know
what language you're going to be speaking. You don't know what the cultural values are that you're going
to have to be able to become a member of this society and things that are expected of you. All of that
has to become through experience through building this value function. So this is, and this is something
we discovered in the 20th century. And now it's going into AI. It's called reinforcement learning
in AI. It's a form of procedural learning, as opposed to the cognitive level where you think and
you do things. Cognitive thinking is much less efficient because you have to go step by step
with procedural learning. It's automatic. Can you give me an example of procedural learning
in the context of a comparison to cognitive learning? Like, is there an example?
of perhaps like how to make a decent cup of coffee using, you know, purely knowledge-based
learning versus procedural learning.
Oh, okay, okay.
Where procedural learning wins.
And I can imagine one, but you're the true expert here.
Well, you know, no, you know a lot of examples, but my, I'll just, since we've been talking
about tennis, can you imagine learning how to play tennis through a book, reading a book?
That's so funny.
On the plane back from Nashville yesterday, the guy sitting across the aisle from me was reading a book about maybe he was working on his pilot's license or something.
And I looked over and couldn't help but notice these diagrams of the plane flying.
And I thought, I'm just so glad that this guy is a passenger and not a pilot.
And then I thought about how the pilots learned.
And presumably it was a combination of practical learning and textbook learning.
I mean, when you scuba dive, this is true.
I'm scuba dive certified, and when you get your certification, you learn your dive tables
and you learn why you have to wait between dives, et cetera, and gas exchange and a number of things.
But there's really no way to simulate what it is to take your mask off underwater, put it back on,
and then, you know, blow the water out of your mask.
Like that, you just have to do that in a pool.
And you actually have to do it when you need to for it to really get drilled in.
Yes.
It's really essential for things that have to be executed quickly.
and expertly to get that really down pat so you don't have to think.
And this happens in school, right?
In other words, you have classroom lessons where you're given explicit instruction,
but then you go do homework.
That's procedural learning.
You do problems.
You solve problems.
And, you know, I'm a PhD physicist, so I went through all of the classes, you know,
in theoretical physics.
And it was really the problems
that really were the core
of becoming a good physicist.
You know, you can memorize the equations,
but that doesn't mean you understand
how to use the equations.
I think it's worth highlighting something
a lot of times on this podcast,
we talk about what I call protocols.
It would be, you know,
like get some morning sunlight in your eyes
to stimulate your super-chaismatic nucleus
by way of your retinal gangling cells.
Audiences of this podcast will recognize those terms.
It's basically get sunlight in your eyes in the morning
and set your circadian clock.
That's right.
And you can hear that a trillion times.
But I do believe that there's some value to both knowing what the protocol is, the underlying
mechanisms, there are these things in your eye that, you know, encode the sunrise qualities
of light, et cetera, et cetera, and then send them to your brain, et cetera, et cetera.
But then once we link knowledge, pure knowledge, to a practice, I do believe that the two things
merge someplace in a way that, let's say, reinforces both the knowledge and the practice.
Right. So these things are not necessarily separate. They bridge. In other words, doing your theoretical
physics problem sets reinforces the examples that you learned in lecture and in your textbooks
and vice versa. So this is a battle that's going on right now in schools. You know, what you've just
said is absolutely right. You need both. We have two major learning systems. We have a cognitive
learning system, which is cortical. We have a procedural learning system, which is subcortical.
Basil gang there. And the two go hand in hand. If you want to become good at anything, the two are
going to help each other. And what's going on right now in schools, in California at least,
is that they're trying to get rid of the procedural. That's ridiculous. They don't want students
to practice because it's going to be, you know, you're stressing them. You don't want them to
feel that, you know, that they're having difficulty. So, but we can, but it can do everything.
I'm covering my eyes because, I mean, this would be like saying, goodness, there's so many examples.
Like, here's a textbook on swimming and then you're going to go out to the ocean someday and you will have never actually swum.
Right.
And now you're expected to be able to survive, let alone swim well.
It's crazy. It's crazy. And I'll tell you, Barbara Oakley has and I have a MOOC, massive open online course on learning how to learn.
And it helps students.
We aimed it at students, but it actually has been taken by four million people, 200 countries, ages 10 to 90.
What is this called?
Learning how to learn.
Is there a paywall?
No, it's free, completely free.
Amazing.
And, you know, I get incredible feedback, you know, fan letters almost every day.
Well, you're about to get a few more.
Okay.
I did an episode on Learning How to Learn, and my understanding of the research is that we need to test ourselves.
on the material. The testing is not just a form of evaluation. It is a form of identifying the
errors that help us then compensate for the errors and learn. But it's very procedural. It's not
about just listening and regurgitating. You put your finger on it, which is that, and this is what
we teach the students, is that you have to, the way the brain works, right, is not, it doesn't
memorize things like a computer, but it has to be active learning. You have to actively engage.
In fact, when you're trying to solve a problem on your own, right? This is where you're really
learning by trial and error, and that's the procedural system. But if someone tells you what the
right answer is, you know, that's just something that is a fact that it gets stored away somewhere,
but it's not going to automatically come up if you actually are faced with something that's not
exactly the same problem, but is similar. And by the way, this is the key to AI, completely
essential for the recent success of these large language models that the public now is beginning
to use, is that they're not parrots. They just don't memorize what the data that they've taken
in. They have to generalize. That means to be able to do well on new things that come in that are
similar to the old things that you've seen, but allow you to solve new problems. That's the key
to the brain. The brain is really, really good at generalizing. In fact, in many cases, you only need
one example to generalize. Like going to a restaurant for the first time, there are a number of new
interactions. There might be a host or a hostess. You sit down at these tables you never sat at.
Somebody asked you questions. You read it. Okay, maybe it's a QR code these days.
But forever after you understand the process of going into a restaurant,
doesn't matter what the genre of food happens to be or what city,
sitting inside or outside.
You can pretty much work it out.
Sit at the counter, sit outside, sit at the table.
There are a number of key action steps that I think pretty much translate to everywhere.
Unless you go to some super high-end thing or some super low-end thing where it's a buffet or whatever.
You know, you can start to fill in the blanks here.
if I understand correctly, there's an action function that's learned from the knowledge and the experience.
Exactly.
And then where is that action function stored?
Is it in one location in the brain or is it kind of an emergent property of multiple brain areas?
So you're right at the cusp here of where we are in neuroscience right now.
We don't know the answer to that question.
In the past, it had been thought that, you know, the cortex,
had, were like countries on, that each of which, each part of the cortex was dedicated to one function, right?
You know, there's, and interestingly, you record for the neurons, and it certainly looks that way, right?
In other words, there's a visual cortex in the back, and there's a whole series of areas,
and then there's an auditory cortex here in the middle, and then the prefrontal cortex for social interaction.
And so it looked really clear cut, that it's modular.
And now we're facing is we have a new way to record from neurons.
Optically, we can record from tens of thousands, from dozens of areas simultaneously.
And what we're discovering is that if you want to do any task, you're engaging, not just the area that you might think has the input coming against the visual system.
But the visual system is getting input from the motor system, right?
In fact, you know, there's more input coming from the motor system than from the eye.
Really?
Yes.
Yeah, Anne Churchill at UCLA has shown that in the mouse.
This is, so now we're looking at global interactions between all these areas.
And that's where real complex cognitive behaviors emerge.
It's from those interactions.
And now we have the tools for the first time to actually be able to see them in real time.
And we're doing that now first.
on mice and monkeys, but we now can do this in humans.
So I've been collaborating with a group at Mass General Hospital to record from people
with epilepsy, and they have to have an operation for people who are drug-resistant,
to be able to find out where it starts in the cortex, you know, and where it is initiated,
where the seizure starts, and then to go in, you have to go in and record simultaneously
from a lot of parts of the cortex for weeks until you find out where it is, and then you go in
and you try to take it out, and often that helps. Very, very invasive, but for two weeks,
we have access to all those neurons in that cortex that are being recorded from constantly.
And so I've used, I started out because I was interested in sleep, and I wanted to understand
what happens in the cortex of a human during sleep. But then we realized, we realized,
that, you know, you can also figure, you know, people who have these debilitating problems with seizures,
you know, there are for two weeks and they have nothing to do. So they just love the fact that scientists are
interested in helping them and, you know, teaching them things and finding out where in the cortex
things are happening when they learn something. This is a gold mine. It's unbelievable. And I've learned
things from humans that I could have never gotten from any other species. Obviously, language
is one of them, but there are other things in sleep that we've, we discovered having to do
with traveling waves. There are circular traveling ways that go on during sleep, which is astonishing.
Nobody ever really saw that before. If you were to ascribe one or two major functions to these
traveling waves, what do you think they are accomplishing for us in sleep? And by the way, are they
associated with deep sleep, slow wave sleep, or with rapid eye movement sleep or both?
This is non-REM sleep.
This is a jargon.
This is during intermediate.
Transition states.
Transition state.
Okay.
Our audience will probably be keep up.
They've heard a lot about slow wave sleep from me and Matt Walker from rapid eye movements.
Light slow wave sleep, yeah.
And so what do these traveling waves accomplish for us?
Oh, okay.
So in the case of the, they're called sleep spindles.
The waves last for about a second or two, and they travel, like I say, in a circle around the cortex.
And it's known that these spindles are important for consolidating experiences you've had during the day into your long-term memory storage.
So it's a very important function.
And if you take out, see, it's the hippocampus that is replaying the experiences.
It's a part of the brain is very important for long-term memory.
If you don't have a hippocampus, you can't learn new things.
That's to say, you can't remember what you did yesterday, or for that matter, even an hour earlier.
But the hippocampus plays back your experiences, causes the sleep spindles now to need that into the cortex.
And it's important you do that right because you don't want to overwrite the existing knowledge you have.
You just want to basically incorporate the new experience into your existing.
knowledge base in an efficient way that doesn't interfere with what you already know.
So that's an example of a very important function that these traveling ways have.
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Huberman. As I recall, there are one or two things that one can do in order to ensure that one gets
sufficient sleep spindles at night and thereby incorporate this new knowledge. This was from the
episode that we did with Gina Poe from UCLA, I believe, and others, including Matt Walker.
My recollection is that the number one thing is to make sure you get enough sleep at night,
so you experience enough of these spindles. And we're all familiar with the cognitive challenges,
including memory challenges and learning challenges associated with lack of sleep,
insufficient sleep.
The other was that there was some interesting relationship between daytime exercise and nighttime
prevalence of sleep spindles.
Are you familiar with that?
Yes.
Oh, yes.
No, this is a fascinating literature, and it's all pointing the same direction, which is that,
you know, we always neglect to appreciate the importance of sleep.
obviously you're refreshed when you wake up, but there's a lot of things happen.
It's not that your brain turns off, it's that it goes into a completely different state.
And memory consolidation is just one of those things that happens when you fall asleep.
And, of course, there's dreams and so forth.
We don't fully appreciate or understand exactly how all the different sleep stages are worked together.
But exercise is a particularly important part of getting.
the motor system
tuned up.
It's thought that the
REM rapid eye movement sleep
may be involved in that.
That's yet another part of the sleep
stages. You go through, you go back and forth
between dream sleep
and the slow-way sleep, back and forth, back and forth
during the night.
And then when you wake up,
you're in the REM stage,
more and more REM, more and more.
But, you know, that's all observation.
But, you know, as a scientist, what you want to do is perturb the system and see if you can
maybe if you had more sleep spindles, maybe you'd be able to remember things better.
So it turns out Sarah Mednick, who was at UC Irvine, did this fantastic experiment.
So it turns out there's a drug called Zolpidum, which goes by the name Ambien.
You may have some experience with that.
I've never taken it, but I'm aware of what it is.
People use it as a sleep aid.
That's right.
A lot of people take it in order to sleep.
Okay.
Well, it turns out that it causes more sleep spendals.
Really?
Yeah.
It doubles the number of sleep spindles.
If you take the drug, you take the drug after you've done the learning, right?
You do the learning at night, and then you take the drug, and you take the drug, and you
have twice as many spindles. You wake up in the morning, you can remember twice as much from what
you learned. And the memories are stable over time? It's like, it's in there.
Yes, yeah. No, it consolidates it. I mean, that's the point. What's the downside of Ambien?
Okay, here's the downside. Okay. So people who take the drug, say if you're going to Europe and you take it,
and then you sleep really soundly, but often you find yourself in the hotel room and you completely have no clue
you have no memory of how you got there.
I've had that experience without Ambien or any other drugs where I am very badly jet lagged.
Yes.
And I wake up for a few seconds, but what feels like eternity, I have no idea where I am.
It's terrifying.
Well, that's another problem that you have with jet lag.
Jet lag really screws things up.
But this is something where it could be an hour.
You know, you took the train or you took a taxi or something, and you're –
Now, this seems crazy.
How could it be a way to improve learning and recall on one hand
and then forgetfulness, on the other hand?
Well, it turns out what's important is that when you take the drug, right?
In other words, it helps consolidate experiences you've had in the past
before you took the drug, but it will wipe out experiences you have.
in the future after you take the drug, right?
So I'm not laughing.
It must be a terrifying experience, but I'm laughing because, you know, there's some beautiful
pharmacology and indeed some wonderfully useful pharmaceuticals out there.
You know, some people may cringe to hear me say that, but there are some very useful
drugs out there that save lives and help people deal with symptoms, et cetera.
Side effects are always a concern.
But this particular drug profile, Ambien, that is, you know, it.
seems to reveal something perhaps even more important than the discussion about spindles or
Ambien or even sleep, which is that you got to pay the piper somehow, as they say.
That's right.
That you tweak one thing in the brain, something else. Something else goes.
You don't get anything for free.
That's a true. I think that this is something that is true, not just of drugs for the brain, but
steroids for the body.
Sure. Yeah, I mean, steroids, even low-dose testosterone therapy, which is very popular nowadays,
we'll give people more vigor, et cetera. But it is introducing a sort of second puberty. And puberty
is perhaps the most rapid phase of aging at the entire lifespan. Same thing with people take growth
hormone would be probably a better example. Because certainly those therapies can be beneficial
to people, but growth hormone gives people more vigor, but it accelerates aging. Look at the quality
of skin that people have when they take growth hormone. It looks more age. They physically change.
And I'm not for or against these things. It's highly individual. But I completely agree with you.
I would also venture that with the growing interest in so-called neutropics and people taking
things like modafinil, not just for narcolepsy, daytime sleepiness, but also to enhance cognitive
function. Okay, maybe they can get away with doing that every once in a while for a deadline
task or something, but my experience is that people who obsess over the use of pharmacology
to achieve certain brain states pay in some other way.
Absolutely.
Whether or not stimulants or sedatives or sleep drugs, and that behaviors will always prevail.
Behaviors will always prevail as tools.
Yeah, and one of the things about the way the body evolved is that it really has to balance
a lot of things.
And so with drugs, you're basically unbalancing it somehow.
And the consequence is, as you point out, is that in order to make one part better,
one part of your body, you sacrifice something else somewhere else.
As long as we're talking about brain states and connectivity across areas, I want to ask a particular question.
Then I want to return to this issue about how best to learn, especially in kids, but also in adulthood.
I've become very interested in and spent a lot of time with the literature and some guess on the topic of psychedelics.
Let's leave the discussion about LSD aside because do you know why there aren't many studies of LSD?
This is kind of a fun one.
No one is expected to know the answer.
Well, it's against the law, I think.
Oh, but there's so is psilocybin or MDMA and there are lots of studies going on about those.
Yeah, it's changed.
But when I was growing up, you know, as you know, it was against the law.
Right.
So what I learned is that there are far fewer clinical trials exploring the use of LSD as a therapy.
Because with the exception of Switzerland, none of the researchers are willing to stay in the laboratory as long as it takes for the subject to get through an LSD journey, whereas psilocybin tends to be a shorter experience.
Okay. Let's talk about psilocybin for a moment. My read of the data on psilocybin is that it's still open to question, but that some of the clinical trials show pretty significant recovery from major depression. It's pretty impressive. But if we just set that aside and say, okay, more needs to be worked out for safety.
What is very clear from the brain imaging studies, before and after, resting state, task-related, et cetera, is that you get more resting state global connectivity, more areas talking to more areas than was the case prior to the use of the psychedelic.
And given the similarity of the psychedelic journey and here specifically talking about psilocybin to things like rapid eye movement, sleep and things of that sort, I have a very simple question.
Do you think that there's any real benefit to increasing brainwide connectivity?
To me, it seems a little bit haphazard, and yet the clinical data are promising, if nothing else, promising.
And so is what we're seeking in life as we acquire new knowledge, as we learn tennis or golf
or, you know, take up singing or what have you, as we go from childhood into the late stages
of our life, that whole transition is what we're doing, increasing.
connectivity and communication between different brain areas. Is that what the human experience is really
about? Or is it that we're getting more modular? We're getting more segregated in terms of this area,
talking to this area in this particular way. Feel free to explore this in any way that feels meaningful.
Or to say pass, if it's not a good question. No, it's a great question. I mean, you have all these
great questions, and we don't have complete answers yet. But specifically, with regard to connectivity,
if you look at what happens in an infant's brain during the first two years,
there's a tremendous amount of new synapses being formed.
This is your area, by the way.
You know about this than I do.
But then you prune them, right?
Then the second phase is that you overabundant synapses,
and now what you want to do is to prune them.
Why would you want to do that?
Well, you know, synapses are expensive.
It takes a lot of energy to activate all of the neurons and the synapses especially,
because there's the turnover of the neurotransmitter.
And so what you want to do is to reduce the amount of energy
and only use those synapses that have been proven to be the most important.
Now, unfortunately, as you get older, the pruning slows down, but doesn't go away.
So the cortex thins and so forth.
So I think it goes in the opposite direction.
I think that as you get older, you're losing connectivity.
But interestingly, you retain the old memories.
The old memories are really rock solid because they were put in when you were young.
They had the foundation.
The foundation upon which everything else is built.
But it's not totally one way in the sense.
that even as an adult, as you know, you can learn new things, maybe not as quickly. By the way,
this is one of the things that surprise me. So Barbara and I have, you know, looked at the people
who, you know, really were the benefit of the most. It turns out that the peak of the demographic is
25 to 35. Barbara Oakley, Oakley. Yeah, she's really the mastermind. She's a fabulous educator
and background in engineering.
But what's going on?
So it turns out we aimed our MOOC at kids in high school and college
because that's their business.
They go every day and they go into work and they have to learn, right?
That's their business.
But in fact, very few of the students who are actually, you know,
they weren't taking the court.
Why should they?
They spent all day in the class, right?
Why did they want to take another class?
So this is the learning to learn class?
Learning how to learn.
Okay.
So you did this with Barbara.
So I did with Barbara.
And now 25 to 35, we have this huge peak, huge.
So what's going on?
Here's what's going on.
It's very interesting.
So you're 25.
You've gone to college.
Half the people, by the way, who take the course went to college, right?
So it's not like, you know, filling in for college.
This is like topping it off.
But you're in the workforce.
course. You have to learn new skill. Maybe you have mortgage. Maybe you have children, right? You can't
afford to go off and take a course or get another degree. So you take a MOOC and you discover,
you know, I'm not quite as agile as I used to be in terms of learning, but it turns out with
our course, you can boost your learning. And so that even though you're not as, your brain is,
is that learning as quickly, you can do it more efficiently.
This is amazing. I want to take this course. I will take this course. What sort of time
commitment is the course? You already pointed out that it's zero cost, which is amazing.
Yeah, yeah. Okay, so it's bite-sized videos lasting about 10 minutes each, and it's about 50 or 60
over course of one month. And are you tested or you self-test? Yeah, there are tests. There are quizzes.
There are tests at the end. And there are forms where you can go and talk
to other students. You have questions. We have TAs. And anyone can do this. Anyone in the world.
In fact, we have people in India, housewives who say, thank you, thank you, because I could have
never learned about how to be a better learner. And I wish I had known this when I was going to
school. Why do more people not know about this learning to learn course? Although, as people know,
if I get really excited about it or about anything, I'm never going to shut up about it. But I'm going to
take the course first because I want to understand the guts of it. You'll enjoy.
it. We have like 98% approval. It's just phenomenal. It's sticky. Is it math? No, no math. No, no
it's not, we're not teaching anything specific. We're not trying to give you knowledge. You're
trying to tell you how to acquire knowledge. And how to do that, how to, how to deal with
exam anxiety, for example, or how to, how to, you know, we all procrastinate, right? We put
things off. No, no, I'm kidding. We all procrastinate.
How to avoid that. We teach you how to avoid that.
Fantastic. Okay, I'm going to skip back a little bit now with the intention of double-clicking on this learning-to-learn thing.
You pointed out that in particular in California, but elsewhere as well, there isn't as much procedural practice-based learning anymore.
I'm going to play devil's advocate here.
And I'm going to point out that this is not what I actually believe.
But, you know, when I was growing up, you had to do your times tables and your division and, you know, and then your fractions and your exponents and, you know, and they build on one another.
And then at some point, you know, you take courses where you might need it like a graphing calculator to some people that can be like, what is this?
But the point being that there were a number of things that you had to learn to implement functions and you learn you learn by doing.
You learn by doing.
Likewise in physics class, we, you know, we were attaching things to strings.
and for macro mechanics and learning that stuff.
Okay.
And learning from the chalkboard lectures.
I can see the value of both, certainly.
And you explained that the brain needs both
to really understand knowledge
and how to implement and back and forth.
But nowadays, you know, you'll hear the argument,
well, why should somebody learn how to read a paper map
unless it's the only thing available
because you have Google Maps?
Or if they want to do a calculation,
they just put it into the top bar function
on the internet and boom out comes the answer. So there is a world where certain skills are no
longer required and one could argue that the brain space and activity and time and energy in
particular could be devoted to learning new forms of knowledge that are going to be more
practical in the school and workforce going forward. So how do we reconcile
these things. I mean, I'm of the belief that the brain is doing math, and you and I agree. It's
electrical signals and it's doing math, and it's running algorithms. I think you convinced us of that,
certainly. But how are we to discern what we need to learn versus what we don't need to learn
in terms of building a brain that's capable of learning the maximum number of things or even enough
things so that we can go into this very uncertain future because as far as you know, and I know
neither of us have a crystal ball. So what is essential to learn? And for those of us that didn't
learn certain things in our formal education, what should we learn how to learn? Well, this is
generational. Okay. So technologies provide us with tools. You mentioned the calculator, right?
Well, a calculator didn't eliminate the education you need to get in math, but it made certain things easier.
It made it possible for you to do more things and more accurately.
However, interestingly, students in my class often come up with answers that are off by eight orders of magnitude.
And that's a huge amount.
It's clear that they didn't key in the calculator properly.
didn't recognize that it was a very far, it was completely way off the beam because they didn't
have a good feeling for the numbers. They don't have a good sense of, you know, exactly how big it
should have been, you know, order of magnitude, basic, you know, understanding. So it's kind of a,
there's a, the benefit is that you can do things faster, better, but then you also lose some of your
intuition if you don't have the procedural system in place. I'm thinking about a kid that
wants to be a musician who uses AI to write a song about a bad breakup that then is kind of
recovered when they find new love. And I'm guessing that you could do this today and get a pretty
good song out of AI. But would you call that kid a songwriter or a musician? On the face of it,
yeah, the AI is helping. And then you'd say, well, that's not the same as sitting down with a guitar
and trying out different chords
and feeling the intonation in their voice.
But I'm guessing that for people that were on the electric guitar,
they were criticizing people on the acoustic guitar.
You know, so we have this generational thing
where we look back and say,
that's not the real thing.
You need to get the...
So what are the key fundamentals
is really a critical question?
Okay, so I'm going to come back to that
because the way you put it at the beginning
had to do with whether you're...
how your brain is allocating resources.
okay. So when you're younger, you can take in things. Your brain is more malleable. For example,
how good are you on social media? Well, I do all my own Instagram and Twitter. And those accounts have
grown in proportion to the amount of time I've been doing it. So yeah, I would say pretty good.
I mean, I'm not the biggest account on social media, but for a science health account, we're doing okay.
Thanks to the audience. Well, this speaks well.
the fact that you've managed to break, you know, to go beyond the generation gap.
I can type with my thumbs, Terry.
Okay, there you go.
That's a manual skill.
That's a new phenomenon in human evolution.
I couldn't believe it.
I saw people doing that.
Now I can do it too.
But the thing is that if you learned how to do that early in life, you're much more good at it.
You can move your thumbs much more quickly.
also you can have many more, you know, tweets going.
What are they called?
No, they're not called tweets.
So on X.
I think they still call them tweets because you can't, it's hard to verb the letter X.
Elon didn't think of that one.
I like X because it's cool.
It's kind of punk and it's got black kind of format and it fits with kind of the, you know,
the engineer like black X, you know, and this kind of thing.
But yeah, we'll still call them tweets.
Okay, we'll call them tweets.
Okay, that's good.
But, you know, I walk across campus and I see everybody, like half the people are tweeting
or, you know, they're doing something with their cell phone.
I mean, it's unbelievable.
And you have beautiful sunsets at the Salk Institute.
We'll put a link to one of them.
I mean, it is truly spectacular, awe-inspiring to see a sunset at the Salk Institute.
Every day is different.
And everyone's on their phones these days?
Sad.
And, you know, they're looking down at their phone and walking along even people who are
skateboarding.
Unbelievable. I mean, you know, it's amazing what the human being can do, you know, when they
learn, get into something. But what happens is the younger generation who picks up whatever
technology it is and the brain gets really good at it. And you can pick it up later, but
you're not quite as agile, not quite as maybe obsessive. It fatigues me. I will point this out,
that doing so doing anything on my phone feels fatiguing in a way that reading a paperbook
or even just writing on a laptop or a desktop computer is fundamentally different.
and I can do that for many hours.
If I'm on social media for more than a few minutes,
I can literally feel the energy draining out of my body.
Interesting.
I could do sprints or deadlifts for hours
and not feel the kind of fatigue
that I feel from doing social media.
So, you know, this is fascinating.
I like to know what's going on in your brain.
Why is it?
And also, I'd like to know from younger people
whether they have the same.
I think not.
I think my guess is that they don't feel fatigue
because they got into this early enough.
And this is actually a very, very, I think that it has a lot to do with the foundation you put into your brain.
In other words, things that you learn when you're really young are foundational,
and they make things easier, some things easier.
Yeah, I spent a lot of time in my room as a kid, either playing with Legos or action figures
or building fish tanks or reading about fish.
I tended to read about things
and then do a lot of procedural-based activities.
You know, I would read skateboard magazines and skateboard.
I was never one to really just watch a sport and not play it.
So, you know, bridging across these things.
So social media, to me, feels like an energy sink.
But, of course, I love the opportunity
to be able to teach to people
and learn from people at such scale.
But at an energetic level,
I feel like I don't have a foundation for it.
It's like I'm trying to like jerry-rig my cognition into doing something that it wasn't designed to do.
Well, there you go.
And it's because you don't have the foundation.
You didn't do it when you were younger.
And now you have to sort of use the cognitive powers to do a lot of what was being done now in a younger person procedurally.
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select juve products. I'm going to tell you something which is going to help all of your listeners,
My book, Chat GDP and the Future of AI, I went through and I looked at other people's experiences with chat GDP.
I just wanted to know what people were thinking.
And I came across, it was an article, I think it was the New York Times, of a technical writer who decided she would spend one month using it to help her write things, her articles.
And she said that when she started out, you know, at the end of the day, she was drained, completely drained.
completely drained
and it was like, you know,
working on a machine,
you know, like a tractor or something,
you know, you're struggling, struggling, struggling
to get it to work.
And then she started, said,
well, wait a second, you know,
what if I treat it like a human being?
What if I'm polite instead of, you know, being curt?
So you said, suddenly,
I started getting better answers
by being polite and, you know, back and forth the way you're with a human, you know.
So saying, could you please give me information about so and so?
Please, I'm really having trouble.
And, you know, that answer you gave me was fabulous.
It's exactly what I was looking for.
And, you know, now I need to go on to the next part and help me with that too.
In other words, the way you talk to a human, right, an assistant.
Or is it that she was talking to the AI to chat GPT, it sounds like in this case,
in the way that her brain was familiar with asking questions to a human?
In other words, can that, so is the AI learning her
and therefore giving her the sorts of answers
that are more facile for her to integrate with?
I think it's both.
I, well, first of all, the chat GDP is mirroring your,
the way you treat it, it will mirror that back.
You treat it like a machine, it will treat you like a machine, okay?
Because that's what it's good at.
But here's the surprise.
Surprise is she said, once I started treating it like a human, at the end of the day, I wasn't fatigued anymore.
Why?
Well, it turns out that all your life, you interact with humans in a certain way, and your brain is wired to do that, and it doesn't take any effort.
And so by treating the chat GDP as if it were a human, you're taking advantage of all the brain circuits in your brain.
This is incredible. And I'll tell you why, because I think many people, not just me, but many people really enjoy social media. Learn from it. I mean, yesterday I learned a few things that I thought were just fascinating about how we perceive our own identity according to whether or not we're filtering it through the responses of others or whether or not we take a couple of minutes and really just sit and think about how we actually feel about ourselves. Very interesting ideas about locus of self-perception and things like that. I also looked at a really cool video of a
maybe raccoon popping bubbles while standing on its hind limbs. And that was really cool. And social
media could provide me both those things within the series of minutes. And I was thinking myself,
this is crazy, right? The raccoon is kind of trivial, but it delighted me. And that's not trivial.
So, but here's the question. Could it be that one of the detrimental aspects of social media
is that if we're complimenting one another or if we are giving hearts or we're giving
thumbs down or we're in an argument with somebody or we're doing a clap back or they're clapping
back on us or dunking as it's called on on on on that it isn't necessarily the way that we learned
to argue. It's not necessarily the way that we learned to engage in healthy dispute. And so as a
consequence, it feels like, and this is my experience, that certain online interactions feel
really good and others feel like they kind of great on me like because there's almost like an action
step that isn't allowed like you can't fully explain yourself or understand the other person right
and i am somebody who you know believes in the in the power of real face-to-face dialogue or at least
on the phone dialogue right and i feel the same way about text messaging i hate text messaging
when text messaging first came out i remember thinking i was not a kid that passed notes in class
this feels like passing notes in class in fact this whole text messaging first
text messaging thing is beneath me. That's how I felt. And over the years, of course, I became a
text messenger. And it's very useful for certain things, be there in five minutes, running a few
minutes late. In my case, that's a common one. But I think this notion of what grates on us,
and as it relates to whether or not it matches our childhood developed template of how our brain
works, is really key because it touches on something that I definitely want to talk about today,
that I know you've worked on quite a bit, which is this concept of energy.
What we're talking about here is energy, not Wu biology, Wu science, wellness, energy.
We're talking about we only have a finite amount of energy.
And years ago, the great Ben Barris sadly passed away, our former colleague and my postdoc advisor,
came to me one day in the hallway and he stopped me and he said, he called me Andy like you do.
and he said, Andy, how can we get so run down of energy as we get older?
Why are we, why am I more tired today than I was 10 years ago?
I was like, I don't know.
How are you sleeping?
He's like, I'm sleeping fine.
Ben never slept much in the first place, but he had a ton of energy.
And I thought to myself, I don't know.
Like, what is this energy thing that we're talking about?
I want to make sure that we close the hatch on this notion of a template neural system
that then you either find experiences invigorating or depleting.
I want to make sure we close the hatch on that, but I want to make sure that we related at some point to this idea of energy.
And why is it that with each passing year of our life, we seem to have less of it?
You know, you ask these great questions.
I wish that I had great answers.
Well, so far you really do have great answers.
They're certainly novel to me in the sense that I've not heard answers of this sort.
So there's a tremendous amount of learning for me today, and I know for the audience.
Okay.
But let's say somebody is 20 years old.
versus 50 years old versus what should they do? I mean, we need to integrate with the modern world.
We also need to relate across generations. Oh, yeah. No, this is true. This is true. People aren't
retiring as much. They're living longer. Birth rates are down, but we have to get all get along, as they say.
So, you know, it is interesting. I think it's true that we all, as we get older, have less of the, you know, the vigor,
vigor, if I could use a somewhat different word from energy. We'll come back to that.
But I think there are some who manage to keep an active life.
Here's something that, again, in our MOOC, we really emphasize.
Could you explain a MOOC?
I think most people won't know what a MOOC is, just for their sake.
Okay, this is, they've been around for about, actually started at Stanford, Andrew Eng, and Daphne Kohler.
So they have a company called Crosera.
And what happens is that you get professors, and in fact, anybody who has knowledge or, you know, professional expertise.
give lectures that are available to anybody in the world who have access to the internet.
And, you know, it could, this is like probably tens of thousands now.
Any specialty, history, science, music, you know, you name it.
There's somebody who's done, you know, who's an expert on that and wants to tell you
because they're excited about what they're doing.
Okay.
So, you know, what we wanted to do was to help people with learning.
And so part of the problem is that it gets more difficult.
It takes more effort as you get older.
It depletes your vigor more if we're going to stay with this language of energy and vigor.
Yeah, that's right.
So let's actually use the word energy.
As you know, in the cell, there is a physical power plant called the mitochondrian,
which is supplying us with ATP, which is the coin of the realm for the cell to be able to operate all of its machinery.
right? So, and so one of the things that happens when you get older is that your mitochondrial run down.
You have fewer of them and they're less efficient. That's right, they're less efficient. And actually
drugs can do that to you too. They can harm mitochondria.
Recreational drugs. No, the drugs you take for illness. I'm not sure about recreational drugs,
but I know it's a case that there are a lot of drugs that people take because they have to. But,
But the other thing, and this is something, that's the bad news.
Here's the good news.
The good news is that you can replenish your energy by exercise.
Exercise is the best drug you could ever take.
It's the cheapest drug you could ever take.
That can help every organ in your body.
It helps, obviously, your heart.
it helps your brain
it
rejuvenates your brain
it helps your immune system
every single organ system
and the body benefits
from a regular exercise
I run on the beach every day
at the Salt Institute
I can
I also at the
it's on a mesa
340 foot above the
so I go down every day
and then I climb up the cliff
yeah those steps down to Blacks Beach
are they're a good workout
they are they are and so this
This is something that has kept me active, and I do hiking.
I went hiking in the Alps this in the last fall.
So this is in September.
So this is, I think, something that people really ought to realize is that, you know,
it's like putting away reserves of energy for, you know, when you get older, the more
you put away, the better off you are.
Here's something else.
Okay, now this is jumping now to Alzheimer's.
So a study that was done in China many, many years ago, when I first came to La Jolla, San Diego,
I heard this from the, it was the head of the Alzheimer's program.
He had done a study in China on onset.
And they went and they had three populations.
They had peasants who had almost no education.
Then they had another group that had high school education.
and then people who were advanced education.
So it turns out that the onset of Alzheimer's
was earlier for the people who had no education.
And it was the latest for the people
who had the most education.
Now, this is interesting, isn't it?
And presumably the genes aren't that different, right?
I mean, they're all Chinese.
So one possibility, and obviously we don't really know why,
but one possibility is that the more you exercise
your brain with education, the more reserve you have later in life.
I believe in the notion, and I don't have a better word for it, maybe you do, or a phrase
for it, is of kind of a cognitive velocity.
You know, I sometimes we'll play with this.
I'll read slowly, or I'll see where my default pace of reading is at a given time of day,
and then I'll intentionally try and read a little bit faster while also trying to retain the knowledge
I'm reading.
Right. So I'm not just reading the words. I'm trying to absorb the information. And you can feel the energetic demand of that. And then I'll play with it. I'll kind of back off a little bit. And then I'll go forward. And I try and find the sweet spot where I'm not reading at the pace that is reflexive, but just a little bit quicker while also trying to retain the information. And I learned this when I had a lot of catching up to do at one phase of my educational career. Fortunately, it was pretty early and I was able to catch up.
on most things, you know, occasionally things slip through and I have to go back and learn how to
learn, you know. And if I get anything wrong on the internet, they sure as heck pointed out. And
then we go back and learn. And guess what? I'd never forget that because punishment,
social punishment is a great signal. Yeah. So thank you all for keeping me learning. But I pick
that up from my experience of trying to get good at things like skateboarding or soccer when I was younger.
there's a certain thing that happens when skateboarding, that was my sport growing up,
where it's actually easier to learn something going faster.
You know, most kids try and learn how to ollie and kickflip standing in the living room on the carpet.
That's the worst way to learn how to do it.
It's all easier going a bit faster than you're comfortable.
It's also the case that if you're not paying attention, you can get hurt.
It's also the case that if you pay too much cognitive attention, you can't perform the motor movements.
Right.
So there's this sweet spot that, of events.
Eventually, I was able to translate into an understanding of when I sit down to read a paper or a news article or even listen to a podcast, there's a pace of the person's voice and then I'll adjust the rate of the audio where I have to engage cognitively and I know I'm in a mode of retaining the information and learning.
Whereas if I just go with my reflexive pace, it's rare that I'm in that perfect zone.
So I point this out because perhaps it will be useful to people.
I don't know if it's incorporated into your learning how to learn course.
But I do think that there is something, which I call kind of cognitive velocity,
which is ideal for learning versus kind of leisurely scrolling.
And this is why I think that social media is detrimental.
I think that we train our brain basically to be slow, passive, and multi-context cycling through.
And unless something is very high salience, it kind of makes us kind of fat and lazy,
forgive the language, but I'm going to be blunt here, fat and lazy cognitively,
unless we make it a point to also engage learning.
And my guess is it's tapping into this mitochondrial system.
Very likely.
That's one part of it.
By the way, the way that you've adjusted the speed is very interesting
because it turns out that stress, you know,
everybody thinks, oh, stress is bad, but no, it turns out stress that is transient,
you know, that is only for a limited amount of time that you control,
is good for you. It's good for your brain. It's good for your body. I run intervals on the beach,
just the way that you do cognitive intervals when you're reading. In other words, I run like hell
for about 10 seconds, and then I go to a jog, and I run like hell for another 10 seconds,
and it's pushing your body into that extra gear that helps the muscles. The muscles need to know that.
This is what they've got to put out. And that's where you gain.
muscle mass, not from just doing the same running pace every day.
Well, your intellectual and physical vigor is undeniable.
I've known you a long time.
You've always had a slight forward center of mass in your intellect,
and even the speed at which you walk, Terry, dare I say.
Okay.
For a Californian, you're a quick walker.
Okay.
Yeah.
So that's a compliment, by the way.
East coasters know what I'm talking about.
And Californians would be like, you know.
Why not slow down?
The reason to not slow down too much for too long is that these mitochondrial systems,
the energy of the brain and body, as you point out, are very linked.
And I do think that below a certain threshold, it makes it very hard to come back,
just like below a certain threshold, it's hard to exercise without getting very depleted or even injured,
that we need to maintain this.
So perhaps now will be a good time to close the hatch on this issue of how to teach young,
people. Everyone should take this learning to learn course as a free resource. Amazing.
As it relates to AI, do you think that young people and older people now, I'm 49, so
put myself in the older bracket, should be learning how to use AI? They are already learning
how to use AI. And again, it's just like new technology comes along. Who picks up first?
It's the younger people.
And it's astonishing.
You know, they're using it a lot more than I am.
You know, I use it almost every day.
But I know a lot of students who basically, and by the way, it's like any other tool, it's a tool that you need to know how to use it.
Where do you suggest people start?
So I have started using Claude AI.
Okay.
This was suggested to me by somebody expert in.
AI as an alternative to chat GPT.
I don't have anything against chat GPT, but I'll tell you, I really like the aesthetic
of Claude AI.
It's a bit of a softer beige aesthetic.
It feels kind of Apple-like.
I like the Apple brand.
And it gives me answers.
Maybe it's the font.
Maybe it's the feel.
Maybe this goes back to the example used earlier where I like Claude AI.
And I'm a big fan of it.
And they don't pay me to say this.
I have never met them.
I have no relationship to them, except that.
It gives me answers in a bullet-pointed format that feels very aesthetically easy to transfer that information into my brain or onto a page.
Right.
So I like Claude AI.
Use chat GPT.
How should people start to explore AI for sake of getting smarter, learning knowledge, just for the sake of knowledge, having fun with it?
What's the best way to do that?
Well, I think exactly what you did, which is there's now dozens and dozens of different chatbots out there.
And different people will feel comfortable with one or the other.
Chat, GDP is the first.
So that's why it's kind of taken over a lot of the cognitive space, right?
It's become like Kleenex, right?
That word.
That was why I used it as the first word in my new book, because it's iconic.
But some of them, I have to say that, for example, there are some that are really much better math than others.
Such as.
Google's Gemini recently did some fine tuning with what's called chain of reasoning.
When you reason, you go through a sequence of steps.
And when you solve a math problem, you go through a sequence of parts of steps of doing, you know,
fitting first finding out what's missing and then adding that.
And it went from 20% correct to 80, right, on those problems.
And as people hear that, they probably think, well, that means 20% wrong still.
But could you imagine any human or panel of humans behind a wall where if you asked it a question and then another question and another question that it would give you back better than 80% accurate information in a matter of seconds?
So I think we are being perhaps a little bit unfair to compare these large.
language models to the best humans rather than the average human, right? As you said,
most people couldn't pass the LSAT, the loss test to get into law school or MCAT the test to get
into medical school. And JetGPT has. Is there a world now where we take the existing AI,
LLMs, these computers basically that can learn like a collection of human brains and send that somehow
into the future, right? Give them an imagined future. Could we give them outcome A and outcome B and let them
forage into future states that we are not yet able to get to and then harness that knowledge
and explore the two different outcomes? I think that's perhaps the
the better question in some sense, because we can't travel back in time, but we can perhaps
travel into the future with AI if you provide it different scenarios. And you say, unlike a panel
of people, panel of experts, medical experts, or space travel experts, or sea travel experts,
you can't say, hey, you know what, don't sleep tonight. You're just going to work for the next
48 hours. In fact, you're going to work for the next three weeks or three months. And you know what?
You're not going to do anything else. You're not going to pay attention to your health. You're not going to do
anything else. But you can take a large language model and you can say just forage for knowledge
under the following different scenarios and then have that fleet of large language models come back
and give us the information like, I don't know, tomorrow. Okay. So I've lived through this myself.
Back in the 1980s, I was just starting my career, and I was one of the pioneers in developing learning algorithms for neural network models.
Jeff Hinton and I collaborated together on something called the Bolshe machine, and he actually won a Nobel Prize for this recently.
Just this year.
Yeah, he's one of my best friends.
Brilliant, and he well deserved it for not just the balsa machine, but all the work he's done since then on machine learning and then back propagation and so forth.
But back then, Jeff and I had this view of the future.
AI was dominated by symbol processing, rules, logic, right?
Writing computer programs.
For every problem, you need a different computer program.
And it was very human resource intensive to write programs
so that it was very, very slow-going.
And they never actually got there.
They never wrote a program for vision, for example,
even though the computer vision computer community really worked hard for a long time.
But, you know, we had this view of the future.
We had this view that nature had solved these problems,
and there's existence proof that you can solve the vision problem.
Look, every animal can see, even insects, right? Come on.
We'll figure out, let's figure out how they did it.
Maybe we can help by following up on nature, we can actually, again, going back to algorithms,
I was telling you.
And so in the case of the brain, what makes it different from a difference,
digital computers basically can run any program, but a fly brain, for example, only runs
the program that it's a special purpose hardware allows it to run. Not much neuroplasticity.
There's enough there, just enough, you know, habituation and so forth, so that you can survive.
And this is- Survept 24 hours. I'm not trying to be disparaging to the fly biologists, but when I think
of a neuroplasticity, I think of the magnificent neuroplasticity of the human brain to customize
to a world of experience. I agree. But when I think about a
fly, I think about a really cool set of neural circuits that, that work really well to avoid getting
swatted to eating and to reproducing and not a whole lot else. They don't really build technology.
They might have interesting relationships, but who knows, who cares. It's just sort of like,
it's not that it doesn't matter. It's just a question of the lack of plasticity makes them kind of a
meh species. Okay, I can see I've crossed your button here. No, no, no, no. I love fly by
They taught us about algorithms for direction selectivity in the visual system.
Oh, no, no, I love the Drosophila biology.
I just think that the lack of neuroplasticity.
Okay.
It reveals a certain, like, key limitation.
And the reason we're the curators of the earth is because we have so much plasticity.
Of course, of course.
But you have to, you know, one step at a time, nature first has to be able to create creatures that can survive.
And then, you know, their brains are bigger as the environment gets more complex.
and here we are.
But the key is that it turns out that certain algorithms in the fly brain are present in our brain,
like conditioning, classical conditioning.
You can classical condition to fly in terms of training it to when you give a reward,
it will produce the same action, right?
This is like conditioned behavior.
And that algorithm that I told you about that isn't your value function, right?
Temporal difference learning.
That algorithm is in the fly brain.
It's in your brain.
So we can learn about learning from many species.
I was just having a little fun poking at the fly biologist.
I actually think Drosophila has done a great deal.
As has honeybee biology, for instance, if you give caffeine to bees on particular flowers,
they'll actually try and pollinate those flowers more because they actually like the feeling of being caffeinated.
There's a bad pun about a buzz here, but I'm not going to make that fun because everyone's done it before.
Right, right. No, I fully absorb and agree with the value of studying simpler organisms to find the algorithms.
Right. That's where we are right now. But now, just go into the future now. I'm telling the story about what we already were. We were predicting the future. We were saying, this is an alternative to traditional AI. We were not taken seriously. Everybody was, experts said, no, no, write programs, right programs. They were getting all the resources.
the grants, the jobs.
And we were just like the little furry mammals
under the feet of these dinosaurs, right?
In retrospect.
I love the analogy.
But the dinosaurs died off.
This is, but the point I'm making is that
it's possible for our brain
to make these extrapolations into the future.
Why not AI versions of brains?
Why not?
I think your idea is a great one.
Yeah, I mean,
the reason I'm excited,
about AI and increasingly so across the course of this conversation is because there are very few
opportunities to forage information at such large scale and around the circadian clock.
I mean, if there's one thing that we are truly a slave to as humans is the circadian biology.
You got to sleep sooner or later.
And even if you don't, your cognition really waxes and wanes across the circadian cycle.
And if you don't, you're going to die early.
we know this. Computers can work, work, work. Sure, you got to power them. There's the
cooling thing. There are a bunch of things related to that, but that's trackable. So computers can
work, work, work. And the idea that they can provide a portal into the future and that they can
just bring it back so we can take a look-see. I'm not saying we have to implement their advice,
but to be able to send a panel of diverse, computationally diverse, experientially diverse,
AI experts into the future and bring us back a panel of potential routes to take.
To me is so exciting.
Maybe a good example would be like treatments for schizophrenia.
This is an area that I want to make certain that we talk about.
You know, I grew up learning as a neuroscience student that schizophrenia,
was somehow a disruption of the dopamine system because if you give neuroleptic drugs that
block dopamine receptors that you get some improvement in the motor symptoms and some of the
hallucinations, et cetera. You now also have people who say, no, that's not really the basis of
schizophrenia. I'd love your thoughts. And you have incredible work from people like Chris Palmer at Harvard,
and we even have a department at Stanford now focusing, we even have people at Stanford now focusing on
what Chris really founded as a field, which is metabolic psychiatry, the idea that
Who could imagine, I'm being sarcastic here, what you eat impacts your mitochondria, how you
exercise impacts your mitochondria, mitochondria impacts brain function.
And woe and behold, metabolic health of the brain and body impacts schizophrenia symptoms.
And he's looked at ways that people can use ketogenic diet, maybe not to cure, but to treat
and in some cases maybe even cure schizophrenia.
So here we are at this place where we still don't have a quote unquote cure for schizophrenia,
but you could send LLMs into the future
and start to forage the most likely
all of the data in those fields.
I could do that in an hour.
Plus come up with a bunch of hypothesized
different positive and negative result clinical trials
that don't even exist yet.
10,000 subjects in Scandinavia
who go on ketogenic diet,
who have a certain level of susceptibility of schizophrenia
based on what we know from twin studies,
things that never, ever, ever would be possible to do in an afternoon,
maybe even in a year.
There's isn't funding.
There isn't.
And boom, get the answers back.
And let them present us those answers.
And then you say, well, it's artificial.
But so are human brains coming up with these experiments.
So to me, I'm starting to realize that it's not that we have to implement everything
that AI tells us or offers us.
But it sure as hell gives us a great window into what.
might be happening or is likely to happen.
Specifically for schizophrenia, I'm pretty sure that if we had these large language models
20 years ago, we would have known back then that ketamine would have been a really good
drug to try to help these people.
Tell us about the relationship between ketamine and schizophrenia.
Okay.
Because I think a lot of people, and maybe you could define schizophrenia, even though most
people think about people hearing voices and psychosis, there's a bit more to it that maybe
we just, you know, bring out the contour. Okay, so one of the things now that we know, see,
the problem is that if you look at the endpoint, that doesn't tell you what started the problem.
It started during early in development. You know, schizophrenia is something that appears
when, you know, late adolescence, early adulthood, but it actually is already a problem,
genetic problem from the get-go. So what is the concordance in identical twins,
meaning if you have one identical twin,
if you have identical twins in the womb,
and one is destined to be full-blown schizophrenic,
what's the probability of the movie?
So here's the experiment.
Okay, this is very, very, been replicated many many times,
in mice, I should say.
Oh, no, actually, it was, okay, let me start with a human.
Okay.
So ketamine is for a long time,
and it still is a party drug, special K.
I've never taken it, but this is what I hear.
I haven't either.
It's a dissociative anesthetic, right?
But I'll tell you what happens, because I've talked to these people who've done this, you take ketamine sub-anesthetic.
By the way, it's an anesthetic.
It's given to children.
It's a pretty good anesthetic, and it's also used veterinary medicine.
But in any case, you give it to, you take young adults, here's what they experience.
They experience, out-of-body experience, you know, they have this wonderful feeling.
of energy, and they're very, you know, it's a high,
but it's a very unusual high.
Now, you know, if they just go and have one experience,
but if they have two, like they party two days in a row,
a lot of them come into the emergency room.
And here's what the symptoms are.
Full-blown psychosis, full-blown.
We're talking about, you know, indistinguishable
from a schizophrenic break.
So auditory hallucinations.
Yeah, auditory hallucinations, you know, paranoia, very, very advanced.
You know, you'd say that, my God, this person here is really, has become a schizophrenic.
And this is really, like you say, the symptoms are the same.
However, if you isolate them for a couple days, they'll come back, right?
So it means that schizophrenia can induce, I'm sorry,
ketamine can't induce a form of schizophrenia, psychosis, temporarily, not permanently, fortunately.
Okay, so what does it attack?
Okay, and there's another literature on this.
It turns out that it binds to a form of receptor, a glutamate receptor, called NMDA receptors,
which are very important by way for learning and memory.
But we know the target, and we also know what the acute outcome is that it reduces
the strength of the inhibitory.
circuit, the interneurons that use inhibitory transmitters, the enzyme that creates the inhibitory
transmitter is downregulated. And what does that do? It means that there's more excitation.
And what does that mean when there's more excitation? It means that there's more activity in the
cortex and there's actually much more vigor and you start becoming crazy, right, if it's too much
activity. So this is interesting. So this is telling us, I think,
that we should be thinking about, and now there's a whole field now in psychiatry that has to do with,
you know, the glutamate hypothesis for the first, where the actual imbalance first occurs.
It's an imbalance between the excitatory inhibitory systems that are in the cortex
keep you in balance.
And NMDA and methyl deospartate receptors are glutamate receptors.
Yes, they are glutamate receptors.
They're one class.
That's one class.
That's right.
Okay, so now here is a hypothesis for why ketamine might be good for depression.
People are taking it now who are depressed, right?
So here you have a drug that causes over-excitation, and here you have a person who is under-excited.
Depression is associated with lower excitatory activity in some parts of the cortex.
Well, if you titrate it, you can come back into balance, right?
So what you do is you fight depression with schizophrenia, a touch of schizophrenia.
Now, you know, you have to keep giving, I think, once every three weeks, they have to have a, you know, a new dose of ketamine.
But it's helped an enormous number of people with very, very severe, you know, clinical depression.
So as we learn more about the mechanisms underlying some of these disorders,
the better we are going to be extrapolating and coming up with some solutions, at least to prevent it getting worse.
By the way, I'm pretty sure that the large language models could have figured this out long ago.
So in an attempt to understand how we might be able to leverage these large language models now,
how would we have used these large language models long ago?
Let's say you had 2024 AI technology in 19.
Let's have fun here.
1998, the year that I started graduate school.
Right.
At that time, it was like the dopamine hypothesis,
schizophrenia was in every textbook.
There was a little bit about glutamate, perhaps,
but, you know, it was all about dopamine.
So how would the large language models have discovered this?
Ketamine was known as a drug.
Ketamine, by the way, is very similar to PCP,
Fenceuclidean, which also binds to,
the NMDA receptor.
So how would, which is also a part of drug.
Which is also, yeah, not one I recommend nor ketamine.
Frankly, I don't recommend any recreational drugs, but I'm not a recreational drug guy.
But what would those large language models do if they, so you've got 2024 technology
placed into 1998, they're foraging for existing knowledge, but then are they able to make
predictions, like, hey, this stuff is going to turn out to be wrong, or hey, this stuff is.
Okay, you know, this is all very, very speculative.
And really, we can begin actually to see this happening now.
So I have a colleague at the Salk Institute, Rusty Gage, very distinguished neuroscientist.
And he was one of the, he discovered that there are new neurons being born.
in the hippocampus, right, which is something in adults, which is something that in a
textbook says that doesn't happen, right?
That was around 1998.
Yeah, yeah, right.
That's right.
And I actually have a paper with him where we tested LTP, long-termotentiation, actually
the effects of exercise on neurogenesis.
Exercise increases neurogenesis.
It increases the cells that increases neurogenesis and also the cells that are become
part of the circuit. More cells become integrated. And this is true in humans as well, right?
Yeah. And there was some cancer drug that was given that, you know, that they showed that it was,
there are new cells that were able, that they were able to later in post-mortem to actually see that
they were born in the adult. Okay. So here we are, okay, in 1998. And the question is,
can you, can you jump? Can you jump into the future? Okay. So Rusty,
We happened to talk about this issue about, you know, he's using these large language models now for his research.
I said, oh, wow, how do you use it?
And he said, we use it as an idea pump.
What do you mean idea pump?
Well, we give it all of the experiments that we've done.
And we have, you know, the literature, it's access to the literature.
and so forth. And we ask it for ideas for new experiments.
Oh, I love it. I love it. I was on a plane where I sat next to a guy that works at Google.
And he's one of the main people there in terms of voice to text and text to voice software.
And he showed me something. I'll provide a link to it because it's another one of these open resource things.
And I'm not super techie. I'm not like the I don't get an F in technology. I don't get an A plus. I'm kind of in the middle.
I think I'm pretty representative of the average listener for this podcast, presumably.
What you show me is that you can take, you open up this website and you can take PDFs
or you can take URLs, so websites, website addresses, and you just place them in the margin.
You literally just drag and drop them there.
And then you can ask questions and the AI will generate answers that are based on the content
of whatever you put into this margin, those PDFs, those.
websites and the cool thing is it references them so you know which one which article it came from
right and and then you can start asking it more sophisticated questions like in the two examples of
the effects of a drug one being very strong and one being very weak which of these papers do you
think is more rigorous based on you know subject number but also kind of the strength of the findings
You know, a pretty vague thing. Strength of findings is pretty vague, right? Anyone that argues those are weak findings, those aren't enough subjects, well, we know a hell of a lot about human memory from one patient, HM. So strength of findings when people is a subjective thing. Right. You really have to be an expert in a field to understand strength of findings and even that. And what's amazing is it starts giving back answers. Like, well, if you're concerned about a number of subjects, this paper, but that's a pretty obvious one, which one had more subjects.
but it can start critiquing the statistics that they used in these papers in very sophisticated ways
and explain back to you why certain papers may not be interesting and others are more interesting
and it starts to weight the evidence.
Oh, my God.
And then you say, well, with that weighted evidence, can you hypothesize what would happen if?
And so I've done a little bit of this where it starts trying to predict the future based on, you know, 10 papers that you gave it five minutes ago.
Amazing.
I don't think any professor could do that except in their very specific area of interest.
And if they were already familiar with the papers, and it would take them many hours, if not days, to read all those papers in detail.
And they might not actually come up with the same answers, right?
Right.
Yeah.
So actually, this is something that is happening in medicine, by the way, for doctors who are using AI as an assistant.
This is really interesting.
So, and this is dermatology, it was a paper in nature, you know, skin lesions.
There's several, 2,000 skin lesions.
Some of them are, you know, cancerous and others are benign.
And so, in any case, they tested the expert doctors and then they tested an AI,
and they were both doing about, you know, 90%.
Right?
However, if you let the doctor use the AI, it boosts the doctor to 98%.
98% accuracy.
Yes.
And what's going on there?
It's very interesting.
So it turns out that although they got the same 90%, they had different expertise that the AI had access to more data.
And so it could look at the lesions that were rare that the doctor may never have seen.
But the doctor has more in-depth knowledge of the most common ones that he's seen over and over again,
and those subtleties and so forth.
So putting them together, it makes so much.
sense that they're going to improve if they work together. And I think that now what you're
saying is that using AI as a tool for discovery with the expert who's interpreting and looking at
the arguments, the statistical arguments, and also looking at the paper maybe in a new way,
maybe that's the future of science. Maybe that's what's going to happen. Everybody's worried
about, oh, AI is going to replace us.
It's going to be much better than we are, everything, and humans are obsolete.
Nothing can be further from the case.
Our strengths and weaknesses are different, and by working together, it's going to strengthen.
It's both, you know, what we do and what AI does, and it's going to be a partnership.
It's not going to be adversarial.
It's going to be a partnership.
Would you say that's the case for things like understanding or,
discovering treatments for neurologic illness, for avoiding, you know, large-scale catastrophes.
Like, can it predict macro movements?
Let me give an example.
Here in Los Angeles, there's occasionally an accident on the freeway.
You have a lot of cameras over freeways nowadays.
You have cameras in cars.
You can imagine all of the data being sent in.
real time. And you could probably predict accidents pretty easily. I mean, these are just moving objects,
right, at a specific rate, who's driving haphazardly. But you could also potentially signal takeover of
the brakes or the steering wheel of a car and prevent accidents. I mean, certain cars already do that,
but could you essentially eliminate, well, let's do something even more important. Let's eliminate
traffic. I don't know if you can do that, because that's a funnel problem. But,
could you predict physical events in the world into the future?
Okay.
This has already been done, not for traffic, but for hurricanes.
So, you know, as you know, the weather is extremely difficult to predict.
And except here in California, where it's always going to be sunny here.
But now what they've done is to feed a lot of previous.
data from previous hurricanes and also simulations of hurricanes.
You can simulate them in a supercomputer.
It takes days and weeks.
So it's not very useful for actually accurately predicting where it's going to hit Florida.
But what they did was after training up the AI on all of this data,
it was able to predict with much better accuracy exactly where in Florida is going to make
landfall. And it does that on your laptop in 10 minutes. Incredible. So something just clicked for me.
And it's probably obvious to you and most people, but I think this is true. I think what I'm
about to say is true. At the beginning of our conversation, we were talking about the acquisition
of knowledge versus the implementation of knowledge, just learning facts versus learning how to implement
those facts in the form of physical action or cognitive action, right? Math problem is cognitive
action, physical action. Okay. AI can do both knowledge acquisition. It can learn facts, long lists
of facts and combinations of facts, but presumably it can also run a lot of problem sets and solve
a lot of problem sets. I don't think, except with some crude still to me, examples of robotics,
that it's very good at action yet, but it will probably get there at some point. Robots are getting
better, but they're not doing what we're doing yet.
But it seems to me that as long as they can acquire knowledge and then solve different problem
sets, different iterations of combinations of knowledge, that basically they are in a position
to take any data about prior events or current events and make pretty darn good predictions
about the future and run those back to us quickly enough and to themselves quickly enough
that they could play out the different iterations.
And so I'm thinking, you know, one of the problems that seems to have really vexed neuroscientists
and the field of medicine and the general public has been like the increase in the,
at least diagnosis of autism.
I've heard so many different hypotheses over the years.
I think we're still pretty much in the fog on this one.
Could AI start to?
to come up with new and potential solutions and treatments,
if they're necessary, but maybe get to the heart of this problem.
It might, and it depends on the data you have.
It depends on the complexity of the disease,
but it will happen.
In other words, we will use those tools the best we can,
because obviously if you can make any progress at all
and jump into the future, wow, that would save lives.
that would help so many people out there.
I really think the promise here is so great
that even though there are flaws and there are regulatory problems,
we just, we really, really have to really push.
And we have to do that in a way that is going to help people,
you know, in terms of making their jobs better
and helping them solve problems,
that otherwise they would have had,
difficulty with and so forth. And it's beginning to happen, but, you know, it's, these are early
days. So we're at a stage right now with AI that is similar to what happened after the first
flight of the Wright brothers. You know, in other words, it's that significant. The achievement that
the Wright brothers made was to get off the ground 10 feet and to power forward with a human being
100 feet, right? That was it. That was the first flight.
And it took an enormous amount of improvements.
The most difficult thing that had to be solved was control.
How do you control it?
How do you make it go in the direction you wanted to go?
Shades of what's happening now in AI is that, you know, we are off the ground.
We were not going very far yet, but who knows where it will take us into the future.
Let's talk about Parkinson's disease, a depletion of dopamine neurons that leads to difficulty
in smooth movement generation and also some cognitive and mood-based dysfunction.
Tell us about your work on Parkinson's, and what did you learn?
So as you point out, Parkinson's is, first, a degenerative disease.
It's very interesting because the dope bean cells are a particular part of the brain stem,
and they are the ones that are responsible for procedural learning.
I told you before about temporal difference.
It's dopamine cells.
And it's a very powerful way for the,
it's a global signal, it's called a neuromodulator
because it modulates all the other signals
taking place throughout the cortex.
And also it's very important for learning,
sequences of actions,
that produce survival for survival.
But the problem is that with certain environmental insults,
especially toxins like pesticides, those neurons are very vulnerable,
and when they die, you get all of the symptoms that you just described.
The people who have lost those cells, actually before the treatment, you know, L-Dopa,
which is a dopamine precursor, they actually became comatose, right?
They didn't move.
They were still alive, but they just didn't move at all.
It's tragic.
Yeah, it locked in, it's called.
Yeah, it's tragic, tragic.
So when the first trials of El Dopa were given to them, it was magical because suddenly they started talking again.
So, I mean, this is amazing, amazing.
I'm curious, when they started talking again, did they report that their brain state during the locked-in phase was slow velocity?
Like, was it sort of like a dreamlike state or they felt like they were in a nap?
Or were they in there, like screaming to get out?
Because their physical velocity obviously was zero.
they're locked in after all.
And I've long wondered when coming back from a run or from waking up from a great night's
sleep when I shift into my waking state, whether or not physical velocity and cognitive velocity
are linked.
Okay, that's a wonderful observation or a question.
I bet you know the answer.
Okay.
Here's something that is really amazing.
It was discovered interestingly when.
They tend to move slowly, as you said.
But to them cognitively, they think they're moving fast.
Now, it's not because they can't move fast,
because you can say, well, can you move faster?
Sure.
And they move normal.
Right?
But to them, they think they're moving at super velocity.
So it's a set point issue.
So it's a set point issue.
Yes, it's all about set points.
That's what's really going on.
And the set point gets further and further down,
you know, now without moving at all,
they think they're moving, right? I mean, this is what's going on? By the way, you can ask them,
you know, what was it like? You know, we were talking to you and you didn't respond. Oh, I didn't
feel like it. The brain confabulates an answer. They have, well, they, they, they, that they
confabulated it because they didn't have enough energy or they couldn't initiate, they couldn't
initiate actions. That's one of the things that they have trouble with it, with movements,
you know, starting a movement. Yeah, as you can tell, I'm fascinated by this notion of cognitive
velocity. And again, there may be a better or more accurate or official language for it, but
I feel like it encompasses so much of what we try to do when we learn and the fact that during
sleep, you have these very vivid dreams during rapid eye movement sleep. So cognitive velocity is
very fast. Time perception is different than in slow wave sleep dreams. And I really think
there's something to it as a at least one metric that relates to brain state. Yes.
I've long thought that we know so much more about brain states during sleep than we do about
wakeful brain states.
We talk about focus, motivated, flow.
I mean, these are not scientific terms.
I'm not being disparaging of them.
They're pretty much all we've got until we come up with something better.
But we're biologists and neuroscientists and computational neuroscientists in your case.
And we're trying to figure out like what brain state are we in right now.
Our cognitive velocity is a certain value.
But I think the more that people think about this, you know, I'll venture to say that the more that they think a little bit about their cognitive velocity at different times of day, start to notice that there's a, tends to be a few times of day.
For me, it tends to be early to late mid-morning.
And then again in the evening after a little bit of trough and energy that, boy, that hour and a half each, like, that's the time to get real work done.
I can have the same experience.
I can mentally sprint far at those times.
Right.
But there are other times of day when I don't care how much caffeine I drink.
I don't care, unless it's a stressful event that I need to meet the demands of that stress,
I just can't get to that faster pace while I'm also engaging.
You can read faster.
You can listen, but you're not using the information.
You're not storing the information.
That's right.
What times a day for you are?
I get most done in morning.
And then you're right, later after dinner is also different, though.
I think in the morning I'm better at creative stuff.
And then I think that in the evening, I'm better at actually just cranking it out, you know.
Interesting.
Given the relationship between body temperature and circadian rhythm, I would like to run an experiment that relates core body temperature to caucus.
I've actually noticed this is something that is just purely subjective, but the temperature
at the salt inside the building is kept 75.
It's like, you know, it's rock solid.
But in the afternoon, I feel a little chilly.
It's probably my internal, you know, internal, you know, body temperature.
Yeah, it's probably going down.
And that may correspond to the loss of energy.
the amount of the ability for the brain and everything else.
By the way, you know, this is Q10, this is a jargon,
every single enzyme in your, every cell can go at different rates
depending on the temperature, right?
And so, yeah, so if the body temperature is doing this,
and all the cells are doing this too, right?
So this is, it's an explanation.
I'm not sure if it's the right one, but.
Yeah, Craig Heller, my colleague at Stanford in the biology department,
has beautifully described how the enzymatic,
control over pyruvate, I believe it is, controls muscular failure. That local muscular failure,
you know, when people are trying to move some resistance, has everything to do with the temperature,
the local temperature that shuts down certain enzymatic processes that don't allow the muscles
to contract the same way. You know, he knows the details and he covered them on this podcast. I'm forgetting
the details. You start to go, wow, like these enzymes are so beautifully controlled by temperature.
and of course his laboratory is focused on ways to bypass those temperature or to change temperature
locally in order to bypass those limitations and have shown them again and again. It's just incredible.
Yeah, I hear we're speculating about what it would mean for cognitive velocity, but I think
it's such a different world to think about the underlying biology as opposed to just thinking about
like a drug. You know, you increase dopamine and norapinephrine and epinephrine, the so-called catacolamines,
and you're going to increase energy focus and alertness,
but you're going to pay the price.
You're going to have a trough in energy focus and alertness
that's proportional to how much greater it was when you took the drug.
Amphetamines are a good example.
Boy, you know, you're going a mile a minute when you're taking the drug.
Of course, you know, it's, I understand that's your impression.
And the reality is you don't actually accomplish that much more.
Have any LLMs, so AI been used?
to answer this really pressing question
of what is going to be the consequence on cognition
for these young brains that have been weaned
while taking riddle in,
Adderall, Vivance, and other stimulants.
Because we have, you know, millions of kids
that have been raised this.
We've done this experiment on our, you know,
a whole cadre, a whole generation.
And, you know, I really would like to know the answer.
I wonder if anybody's studying it.
That's really a great question.
Because we gave them speed effectively,
you know, the drug that causes,
the brain to be activated.
But by the way,
but, you know,
the, you know,
there's the consequence is that, you know,
when it wears off, you have no energy.
Right.
You just completely spent.
Yeah, that's it.
That's the pit.
That's the pit.
And so, and,
but that's why you take more of it, you see.
That's the problem.
It's a spiral.
I love how today you're making it so very clear.
how computation, how math and computers and AI now are really shaping the way that we think about
these biological problems, which are also psychological problems, which are also daily challenges.
I also love that we touched on mitochondria and how to replenish mitochondria. I want to make sure
that we talk about a couple of things that I know are in the back of people's minds, no pun intended
here, which are consciousness and free will. Normally I don't like to talk about these things, not because
they're sensitive, but because I find the discussions around them typically to be more philosophical
than neurobiological, and they tend to be pretty circular. And so you get people like Kevin Mitchell,
who's a real, I think he has a book about free will. He believes in free will. You've got people
like Robert Sapolsky, wrote the book determined. He doesn't believe in free will. How do you feel about
free will? And is it even a discussion that we should be having? Well, if you go back 500 years,
you know, the middle ages.
The concept didn't exist, or at least not in the way we use it.
Because everybody, it was the way that we, that humans felt about the world and how it worked
and its impact on them was that it's all fate.
They had this concept of fate, which is that there's nothing you can do that something
is going to happen to you because of what's going on in the gods above or whatever it is,
right? You attribute it to the physical forces around you that caused it. Not to your own free will,
not to something that you did that caused you to this to happen to you, right? So I think that these
words, by the way, that we use free will, consciousness, intelligence, understanding,
they're weasel words because you can't pin them to.
down. There is no definition of consciousness that everybody agrees on. It's tough to solve a
problem, a scientific problem, if you don't have a definition that you can agree on. And, you know,
there's this big controversy about whether these large language models understand language or not,
right, the way we do. And what it really is revealing is we don't understand what understanding is.
Literally, we don't have a really good argument or measure that you can measure someone's understanding
and then apply it to the CHAP GDP and see whether it's the same.
It probably isn't exactly the same, but maybe there's some continuum here we're talking about, right?
You know, the way I look at it, you know, it's as if an alien suddenly landed on Earth
and started talking to us in English, right?
And the only thing we could be sure
of it was that it's not human.
I met some people that I wondered about their terrestrial origins.
Okay, okay.
Well, okay, now there's a big diversity amongst humans, too.
You're right about that.
Yeah, yeah.
Certain colleagues of ours at UCSD years ago,
one in particular in the physics department,
who I absolutely adore as a human being,
just had such an unusual pattern
of speech,
of behavior,
totally appropriate behavior,
but just unusual.
In the middle of a faculty meeting
would just kind of turn to me
and start talking
while the other person was presenting.
And I was like, maybe not now.
And he would say,
oh, okay.
But in any other domain,
you'd say he was very socially adept.
And so, you know,
there's certain people
that just kind of discard with convention
and he kind of wonder, like,
is he an alien?
It's kind of cool,
in a cool way.
Like, you know,
he's one of my,
again, a friend,
somebody I really delight in.
It's true.
It's true.
You know, no, no, not everybody has adopted the same social conventions.
You know, it could be a touch of autism.
Mm-hmm.
I mean, yeah.
That's a problem that, I mean, in other words, they're very high-functioning autistic people out there.
He's brilliant.
And often they are, you know, it's, there are high people who are brilliant with autism.
But, you know.
Could you build an LLM that was more,
on one end of the spectrum versus the other to see what kind of information they forage for?
I reviewed a paper.
It seemed like it would be a really important thing to do.
It's been done.
Okay, there was a paper that I reviewed where they took the L.M.
And they fine-tuned it with different data from people with different disorders, you know,
autism and so forth.
And sociopaths, you know.
That's scary.
But you want to know the answer?
No, no.
And they got these LLMs to behave just like those people who have these disorders.
You can get them to behave that way, yes.
Could you do political leaning and values?
I haven't seen that, but it's pretty clear that, to me, at least, that if you can do sociopathy,
you can probably do any political belief, you know.
But you could also view all this as you could take benevolent tracks.
You could also say hyper-creative, sensitive to emotional tone of voices and find out what kind of information that person brings, excuse me, that LLM brings back versus somebody who is very oriented towards just the content of people's words as opposed to what, you know, because among people, you find this.
You know, if you've ever left a party with a significant other and sometimes someone will say, I've had this experience.
with like, did you see that interaction between so and so?
I'm like, no, what are you talking about?
Like, did you hear that?
I'm like, no, not at all.
I didn't hear, I heard the words, but I did not pick up on what you were picking up on.
Right.
And it was clear that there's two very different experiences of the same content based purely on a difference in interpretation of the tonality.
Okay.
There's a lot of information that, as you point out, which has to do with the tone, the spatial expressions.
you know, there's a tremendous amount of information that is past, not just with words,
but with all the other parts of the visual input and so forth.
And some people are good at picking that up and others are not.
There's a tremendous variability between individuals.
And, you know, that's, biology is all about diversity.
And it's all about, you know, needing gene pool that's very diverse so that you can evolve
and survive catastrophic changes.
that occur in a climate, for example.
But wouldn't it be wonderful
if we could create LLM
that could understand
what those differences are?
Now, just think about it, right?
Like a truly diverse LLN
that integrated all those differences.
Here's what you'd have to do.
What you'd have to do
is to train it up on data
from a bunch of individuals, human individuals,
Now, one of the things about these LLMs is that they don't have a single persona.
They can adopt any persona.
You have to tell it what you're expecting from.
Or ask it in a way that works for you and you'll get back a certain persona.
I once gave it an abstract from a paper, very technical, computational paper.
And I said, you are a neuroscientist.
I want you to explain this abstract to a 10-year-old.
It did it in a way that I could never have done it.
Was it accurate?
Was it accurate?
It, some of the subtleties were not in it, but explained, you know, what plasticity it was and
explain what a synapse is.
You know, it did that.
It's almost like a qualifying exam for a graduate student.
I saw something today on X, formerly known as Twitter, that blew my mind that I wanted
your thoughts on that was very appropriate to what you're saying right now, which is someone
was asking questions of an LLM on chat GPT or, you know.
maybe one of these other anthropic or clod or something like that.
I probably misuse those names.
One of the AI online sites.
And somewhere in the middle of its answers, the LLM decide to just take a break and start
looking at pictures of landscapes in Yosemite.
Like the LLM was doing what a maybe cognitively fatigued person or what any kind of
of online person online would do, which was to like take a break and look at a couple pictures
of something. Maybe they're thinking about going camping there or something and then get back
to whatever task. We hear about hallucinations in AI, that it can imagine things that aren't there,
just like a human brain. But that blew my mind. I haven't encountered that. But, you know,
it's fascinating. That's a sign of a real generative internal model. If, if it's a factoring, you know,
that's a sign of a real generative internal model.
See, here's the thing that,
the thing that most distinguishes, I think,
in LLM from a human is that, you know,
if you go into a room, quiet room,
and just sit there without any sensory stimulation,
your brain keeps thinking, right?
In other words, you think about what you want to do,
you know, planning ahead,
or something that happened to you during the day,
right, your brain is always generating internally.
You know, after talking to you,
one of these large language models just goes blank.
There is no self-continuous, self-generated thoughts.
And yet we know self-generated thought,
and in particular brain activity during sleep,
as you illustrate earlier with an example of sleep spindles
and rapid eye movement sleep,
are absolutely critical for shaping the knowledge that we were experienced during the day.
So these LLMs are not quite where we are at yet.
I mean, they can outperform us in certain things like Go, but how soon will we have LLMs,
AI, that is, with self-generated internal activity?
we're getting closer and so this is something I'm working on myself actually trying to understand
how that's done in our own brains was generating continual brain activity that leads to
you know planning and things that we don't know what the answer to that is yet in neuroscience
and by the way you go to a lecture and you hear the words one after the next over an hour and you
you see the slides when after the next.
At the end, you ask a question, right?
Just let's think about what you just did.
Somehow you're able to integrate all that information over the hour
and then use your long-term memory
then to come up with some insight or some issue that you want.
How did your brain remember all that information,
working memory, traditional working memory that neuroscientist studies
only after a few seconds, right?
or maybe a telephone number or something.
But we're talking about long-term working memory.
We don't understand how that is done.
And LLMs, actually large language models, can do something.
It's called in-context learning.
And it was a great surprise because there is no plasticity.
The thing learns at the beginning, you train it up on data,
and then all it does after that is to inference, you know,
fast loop of activity, one word after the next, right? That's what happens with no learning, no learning.
But it's been noticed that as you continue your dialogue, it seems to get better at things.
How could that be? How could it be in context learning, even though there's no plasticity?
That's a mystery. We don't know the answer to that question yet. But we also don't know what the answer is for humans.
Right. Could I ask you a few questions about you and as it relates to science and your trajectory?
Building off of what you were just saying, do you have a practice of meditation or eyes closed, sensory input reduced or shut down to drive your thinking in a particular way?
Or are you, you know, at your computer talking to your students in postdocs and sprinting on the beach?
Or a sleet.
No, it's funny you mention that because I get my best ideas, not sprinting on the beach,
but just either walking or jogging.
And it's wonderful.
I don't know.
I think serotonin goes up.
It's another neuromodulator.
I think that that stimulates ideas and thoughts.
And so inevitably, I come back to my office, and I can't remember any of those great ideas.
What do you do about that?
Well, now I take notes.
Okay.
Voice memos?
Yeah. And some of them are to pan out. You know, there's no doubt about it.
Sure. You're put into a situation. It is a form of meditation. You know, if you're running in a steady pace, nothing distracting about, you know, the beach.
Do you listen to music or podcasts? No, I never listen to anything except my own thoughts.
So there's a former guest on this podcast who, she happens to be triple-degreed from Harvard, but she's more in the,
kind of like personal coach space, but very, very high level and impressive mind, impressive
human all around.
And she has this concept of wordlessness that can be used to accomplish a number of different
things, but this idea that allowing oneself or creating conditions for oneself to enter states
throughout the day or maybe once a day of very minimal sensory input, no lecture, no podcast,
no book, no music, nothing.
and allowing the brain to just kind of idle and go a little bit non-linear, if you will.
Right.
Where we're not constructing thoughts or paying attention to anyone else's thoughts through those media venues
in any kind of structured way as a source of great ideas and creativity.
It's been studied.
Psychologists call it mind wandering.
Mind wandering.
Yeah, it is a significant literature.
And it's often when you have an aha moment, right?
And, you know, your mind is wandering and it's thinking nonlinearly in the sense of not following
a sequence that is logical, you know, hopping from thing to thing.
Often that's when you get a great idea, just letting your mind wander.
Yeah, and that happens to me.
I wonder whether social media and just texting and phones in general have eliminated a lot of
the, you know, walks to the car after work where one would normally not.
be on a call or in communication with anyone or anything. I used to do experiments where I was,
you know, like pipetting and running, you know, amino hystochemistry. And it was very relaxing.
And I could think while I was doing because I knew the procedures. And then, you know, you had to
pay attention to certain things, write them down. But I would often feel like, wow, I'm both
working and relaxing and thinking of things. And then I would listen to music sometimes.
Okay. So we have a whole session, you know, a clip.
in learning how to learn about exactly this phenomenon.
Here's what we tell our students, right?
Is that, you know, if you're having trouble with some concept
or, you know, you don't understand something,
you're beating your head against the wall,
don't, stop, stop.
Just go off and do something.
Go off and clean the dishes.
Go off and, you know, walk around the block.
And inevitably, what happens is when you come back,
your mind is clear and you figure out what to do.
And that's one of the best pieces of advice that anybody could get
because we don't, nobody has told us how the brain works, right?
Some people are really good at intuitings because they've experienced maybe.
But everybody I know, okay, the other thing is everybody I know
who's really made important contributions.
And I'll bet you're one of them.
You know, you're struggling with some problem at night and you go to bed and you wake up in the morning.
Ah, that's the solution.
That's what I should do, right?
First thing in the morning when I wake up is when I'm almost bombarded with, I wouldn't say insight and not always meaningful insight, but certainly what was unclear becomes immediately clear on waking.
That's right. That's the thing that is so amazing about sleep.
and you can see people who know this can count on it.
In other words, the key is to think about it before you go to sleep.
Right?
Your brain works on it during the sleep period, right?
And so, you know, don't watch TV because then who knows what your brain's going to work on.
You know, use the time before you fall asleep to think about something that is bothering you
or maybe something that, you know, you're trying to understand, maybe, you know, a paper that you read the paper.
and say, oh, you know, I'm tired. I'm going to go to sleep. You wake up at the morning and say,
oh, I know what's going on in that paper. Yeah, I mean, that's what happens. You can use, you know,
once you know something about how the brain works, you can take advantage of that.
Do you pay attention to your dreams? Do you record them?
No, no. Okay. So here's the problem. Dreams seem so iconic.
And a lot of people, you know, somehow attribute things to them.
But there has never been any good theory or any good understanding, first of all, why we dream.
It's still not completely clear.
I mean, there are some ideas.
Or why this particular dream, does that have some significance for you?
And the only thing that I know that might explain a little bit is that the dreams are often very visual.
you know, rapid eye movement sleep so that there's something happening.
Actually, it's interesting.
All the neuromodulators are downregulated during sleep,
and then during REM sleep, the Cetocoline comes up, right?
So that's a very powerful neuromodulator.
It's important for attention, for example.
But it doesn't come up in the prefrontal cortex.
Which means that the circuits in the prefrontal cortex
that are interpreting the sensory input coming in
are not turned on.
So any of these, whatever happens in your visual cortex is not being monitored anymore.
So you get bizarre things, you know, that you start floating and, you know, things happen to you.
And, you know, it's not anchored anymore.
And so, but that still doesn't explain why, right, why you have that period.
It's important because if you block it and there are some sleeping pills that do block it, you know,
it really does cause problems with, you know, normal cognitive function.
Cannabis as well.
People who come off cannabis experience a tremendous REM rebound.
And lots of dreaming in the days and weeks and months after cannabis.
I don't want to call it withdrawal because that has a different meaning.
No, no.
It's an imbalance that was cause because the brain adjusted to the endocannabinoid levels.
and now it's got to go back and then it takes time.
But it's interesting.
It's an interesting.
It affects dreams.
I think that may be a clue.
Yeah, very common phenomenon.
I'm told I'm not a cannabis user, but no judgment there.
I just am not.
It's actually a book I read years ago when I was in college, so a long time ago, by
Alan Hobson, who was out at Harvard.
Oh, yeah, I know him.
Oh, cool.
So I never met him.
But he had this interesting idea that dreams, in particular rapid eye movement dreams, were so very similar to the experience that one has on certain psychedelics, LSD, lysergic acid, diethythmide, or psilocybin, and that perhaps dreams are revealing the unconscious mind, you know, and not saying this in any psychological terms, you know, that, you know, when we're asleep, our conscious mind can't control thought and action in the same way, obviously.
and kind of a recession of the water line, you know, so we're getting more of the unconscious
processing revealed.
You know, that's an interesting hypothesis.
How would you test it?
I'd probably have to put someone in a scanner, have them to go to sleep, put them in the scanner
on a psilocybin journey, this kind of thing.
You know, it's tough.
I mean, any of these observational studies, of course, we both know, are deficient in the sense
that what you'd really like to do is control them.
neural activity. That's right. You'd like to get in there and tickle the neurons over here and see how
the brain changes and you'd love to get real-time subjective report. This is the problem with sleep
and dreaming is you can wake people up and ask them what they were just dreaming about,
but you can't really know what they're dreaming about in real time. It's true. Yeah, it's true.
By the way, you know, there are two kinds of dreams. Very interesting. So if you wake someone up
during REM sleep, you get very vivid changing. Dreams that are.
They're always different and changing.
But if you wake someone up during slow-wave sleep, you often get a dream report, but it's
a kind of dream that keeps repeating over and over again every night.
And it's a very heavy emotional content.
Interesting.
That's in slow-wave sleep.
Yeah.
Because I've had a few dreams over and over and over throughout my life.
So this would be in slow-wave sleep.
Yeah, probably slow-wave sleep, yeah.
Fascinating.
as a neuroscientist who's computationally oriented, but really you incorporate the biology so well into your work.
So that's one of the reasons you're you, you're this luminary of your field.
And who's also now really excited about AI, what are you most excited about now?
Like if you had, and of course this isn't the case, but if you had like 24 more months to just pour yourself into something and then you had to, you had to, you had to, you had to, you had to, you had to.
hand the keys to your lab over to someone else, what would you go all in on?
Well, so the NIH has something called the Pioneer Award.
And what they're looking for are big ideas that could have a huge impact, right?
So I put one in recently.
And here's the title is a temporal context in brains and transformers.
And in brains and transforms?
Transformers.
Formers.
AI.
Right.
The key to chat GTP is the fact there's this new architecture, it's a deep learning architecture,
feed forward network, but it's called a transformer.
And it has certain parts in it that are unique.
It's one called self-attention.
And it's a way of doing what it's called temporal context.
What it does is it connects words that are far apart.
You give it a sequence of words, and it's a sequence of words.
and it can tell you the association.
Like if you use the word this,
and then you have to figure out in the last sentence,
what did it refer to?
Well, there's three or four nouns.
It could have referred to.
But from context, you can figure out which one it does.
And you can learn that association.
Could I just play with another example
to make sure I understand this correctly?
I've seen these word bubble charts.
Like if we were to say piano, you'd say keys,
you'd say music, you'd say seat,
and then it kind of builds out a word cloud
of association. And then over here we'd say, I don't know, I'm thinking about the Salt
Institute, I'd say, sunset, Stonehenge, anyone that looks at, there's this phenomenal,
Salchhenge. Then you start building out a word cloud over there. These are disparate things,
except I've been to a classical music concert at the Salc Institute.
Symphony is Alt. Twice. So they're not completely not overlapping. And so you start getting
associations at a distance and eventually they bridge together. Is this what you're referring to?
Yes. I think that that's an example.
example, but it turns out that every word is ambiguous as like three, four meetings. And so you have to
figure that out from context. In other words, there are words that live together and that come up often.
And you can learn that from just by predicting the next word in a sentence. That's how a transformer
is trained. You give it a bunch of words and it keeps predicting the next word in a sentence.
Like in my email now, it tries to predict the next word.
Exactly.
And it's mostly right part of the time.
Okay, well, that's because it's a very primitive version of this algorithm.
What happened is if you train it up on enough,
not only can it answer the next word,
it internally builds up a semantic representation
in the same way you describe the words that are related to each other,
having associations, it can figure that out
and it has representations inside this very large network.
work with trillions of parameters, unbelievable how big they had gotten. And those associations now
form an internal model of the meaning of the sentence. Literally, it's been, this is something that
now we've probed these transformers, and so we pretty much are pretty confident. And that
that means that it's forming an internal model of the outside world, in this case a bunch of words.
And that's how it's able to actually respond to you in a way that is sensible, that makes sense,
and actually is interesting, and so forth. And it's all the self-attention I'm talking about.
So in the case, my pioneer proposal is to figure out how does the brain do self-attention?
Right? It's got to do it somehow. And I'll give you a little here.
hint, basal ganglia.
It's in the basal ganglia.
That's my hypothesis.
Well, we'll see.
I mean, you know, I'll be working with experimental people.
I've worked with John Reynolds, for example, who studies primate visual cortex, and we've looked
at traveling ways there, and there are other people that have looked at in primates.
And so now these traveling waves, I think, are also a part of the puzzle, you know, the puzzle, pieces of the puzzle that are going to give us a much better view of how the cortex is organized and how it interacts with the basal ganglia.
We've already been there.
But we're still, you know, neuroscientists have studied each one of these parts of the brain independently.
And now we have to start thinking about putting the pieces of the puzzle together, right?
trying to get all the things that we know about these areas and see how they work together in a
computational way. And that's really where I want to go. I love it. And I do hope they decide to fund
your Pioneer Award. I do too. Yeah. And should they make the bad decision not to, you know,
maybe we'll figure out another way to get it, get the work done. Certainly you will. Terry,
I want to thank you. First of all, for coming here today, taking time out of your
busy cognitive and running and teaching and research schedule to share your knowledge with us.
And also for the incredible work that you're doing on public education and teaching the public,
I should say, giving the public resources to learn how to learn better at zero cost.
So we will certainly provide links to learning how to learn and your book and to these other
incredible resources that you've shared.
And you've also given us a ton of practical tools today related to,
exercise mitochondria and some of the things that you do, which of course are just your versions of what
you do, but that certainly, certainly are going to be a value to people, including me in our
cognitive and physical pursuits and frankly just longevity. I mean, this is not lost on me in those
listening that your vigor is, as I mentioned earlier, undeniable. And it's been such a pleasure
over the years to just see the amount of focus and energy and enthusiasm that you bring to your
work and to observe that it not only hasn't slowed, but you're picking up velocity. So thank you so
much for educating us today. I know I speak on behalf of myself and many, many people listening and
watching is this a real gift, a real incredible experience to learn from you. So thank you so much.
Well, thank you. And I have to say that I've been blessed over the years with wonderful students
and wonderful colleagues, and I count you among them, who really, I've learned. I've learned
a lot from.
Thank you.
But, you know, science is a social activity.
And we learn from each other.
And we all make mistakes.
But we learn from our mistakes.
And that's the beauty of science is that we can make progress.
Now, you know, your career has been remarkable too
because you have affected and influenced more people
than anybody else I know personally with the knowledge
that you are broadcasting through your interviews, but also, you know, just in terms of your
interests.
Really, I'm really impressed what you've done.
And I want you to keep, you know, at it because we need people like you.
We need scientists who can actually express and reach the public.
If we don't do that, everything we do is behind closed doors, right?
Nothing gets out. And so you're one of the best of the breed in terms of being able to explain things in a clear way that gets through to more people than anybody else I know.
Well, thank you. I'm very honored to hear that. It's a labor of love for me. And I'll take those words in, and I really appreciate it. It's an honor and a privilege to sit with you today. And please come back again.
I would be a love to. I would love to, you know.
All right. Thank you, Terry.
You're welcome.
Thank you for joining me for today's discussion with Dr. Terry Sinooski.
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