Improve Energy & Longevity by Optimizing Mitochondria | Dr. Martin Picard

What's the deal? Can people reverse the graying of their hair by reducing their stress? Can people accelerate the graying of their hair by stressing more? Likely both are true, yes. Okay. And I think what we discovered is that hair graying...

at least temporarily, is reversible. This was surprising because it goes against this notion that aging is a linear process that just happens over time, no matter what you do. And here we should know, actually, a hallmark of aging, which is... you know depigmentation losing color in your beard and your hair um it's something that happens

to almost everyone, but at different stages of life and so on. And then on the same person, and the reason we got into this was that this felt like the perfect experiment. Every hair has the same genome. They're all genetically identical twins. Right. And they're all exposed to the same exercise regime, the same food, the same stress levels. Yet some hairs go gray when you're like late 30s and then some hairs go gray when you're like in your 80s.

What the hell is happening? If we could figure this out, maybe we can understand why different people age at different rates. Because it's very clear that there's no more than 10% of how long you live that's genetically driven. Like the best studies put this at around 7%. 7% of longevity is genetically inherited maybe, and then about 90% is not. 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. Martin Picard. Dr. Martin Picard is a professor of behavioral medicine at Columbia University. He is also a leading expert on how your daily behaviors and your mode of thinking, meaning your psychology, change energy production in your cells and can accelerate or reverse biological aging.

Most people have heard of mitochondria as the energy producing organelles within their cells. And of course, that's linked to what we call metabolism and metabolic health. And of course, most people understand that eating properly, exercising and sleep are critical for metabolic health. But it turns out that's only part of the story.

As Dr. Picard explains, mitochondria don't just make energy. They act as sort of antennas to link your psychological experiences to your organ health, your rate of aging, and your sense of vigor, meaning your mental and physical readiness. He explains that how well your mitochondria work in different organs and brain areas reflects what specific forms of exercise you do, as well as how you think and how you manage stress.

Today, he explains the things that you can do to enhance mitochondrial function that go beyond the typical get sleep, eat right, and exercise advice. His lab has shown that aging is not linear. It's not just a progression from youth to death where your mitochondria decline over that time. At different ages and stages, mitochondrial health drops off like a cliff, but there are critical things that you can do.

in terms of how you eat, your mindset and exercise that can offset those changes. His lab also famously showed that graying of hair is indeed related to stress and is also fortunately reversible. By the end of today's episode, you will not only have had a masterclass in mitochondria, he explains mitochondria with immense clarity so that you really will understand how these incredible organelles work to produce energy and as the sort of antennas to direct that energy.

from outside you and by the things you do. And by the end of today's episode, you'll also have a lot of actionable items that you can apply toward your health and to offset aging.

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, today's episode does include sponsors and now for my discussion with dr martin picard dr martin picard welcome thank you your work is so relevant nowadays i suppose it was relevant always but

These days, we hear so much about mitochondria. Most people have perhaps heard of mitochondria. They think the powerhouse of the cell, but you're going to tell us that it's a lot more than that. And I should say right off the bat,

That if people think that perhaps a discussion about these little organelles we call mitochondria is not for them, keep in mind, Martin's laboratory was the one that discovered that you can indeed reverse the graying of your hair. That graying of hair is not a prerequisite.

of aging. There's some other ways that hair gray. So we'll get to that later. Super interesting work. I have a million questions for you. Let's start off with the most important and most basic question, which is what is this thing that we call energy? There's electrical energy. We know the sun gives us energy, et cetera. But when we're talking about the energy of life, physical and mental vigor, the feeling that we want to do something as opposed to have to force ourselves to do it.

What is this at the organism and cellular level? I mean, even physicists don't agree on what energy... is. And there's been debates, you know, Richard Feynman, who was like this amazing science communicator physicist, said that we don't even know what energy is and what's the best way to define it, because there are all of these forms.

Thermal energy, heat, right? Light energy, electromagnetic, kinetic energy, movement, speed, right? Potential energy. So energy kind of manifests in all of these different ways.

In a nutshell, I think the best definition I've heard from my wife, Narosha, who's a biophysicist, energy is the potential for change. And that applies to any kind of... form any form of energy you can think about it's the potential for change for changing something in the system and that's uh i think an accurate description of you know thermal energy if something is frozen solid

There's no, you know, potential for moving something. We need to be at 37 Celsius, right? The human body. It gives us the potential to move and muscles to contract and, you know, our biology to... to function. So this is just one example where there's like a sweet spot of energy or there needs to be some thermal energy. You need to be a little warm to be alive.

So the potential for change, and then it manifests in all these beautiful ways. And it's something that flows. You know, a key property of energy is something that has the ability to flow and to transform. So you can never create nor destroy energy, right? That's like a fundamental law of thermodynamics. But energy always transforms. So you can transform heat, right, into motion. Like the steam engine, for example, through pressure, another form of energy. Or you can transform electricity.

into, you know, a picture on your screen. That's, you know, what your computer does. Transforms your raw energy, electricity into, you know, a picture, a sound. So that's what happens. all around us. It's all, you know, energy moving, transforming energy from the sun. This outer, you know, reactor and, you know, nuclear reactor in outer space beams energy at us. And then what plants do is they take that energy, transform, you know, light into

biochemistry. And then you get energy, which used to be immaterial, that gets crystallized into biochemistry. And then we, human beings, animals... eat that biochemical energy and then the inner mitochondria that energy gets transformed right again the potential for change and then the that biochemical energy gets transformed into an electrochemical gradient You charge your little batteries, your mitochondria. And then that's another form of energy.

which, again, is a potential for change. And then you can make ATP with this. You can make reactive oxygen species. You can make hormones. You can, you know, all of the beautiful things that mitochondria do. So energy is that potential for change that has all of these different forms that continuously transforms.

Amazing. Or you can use your brain to create technologies that create other forms of energy or excuse me transform other forms of energy exactly uh and your question was about you know the the human energy vitality like you know the the the energy to do something and that's i think another man

manifestation of energy. As energy flows through this thing that we call biology or the human body, it kind of moves us into action, right? And we know from first principles that... The basis for human experiences, the mind and our ability to be inspired, to feel positive things or to feel negative things, depends on the flow of energy. The difference between a thinking, feeling, conscious person having experiences and being able to go to the gym and lift and a cadaver.

It's really, it's not the size of the muscles, the number of cells, the nucleus, the genes, the mitochondria. It's none of this. The difference between a living person and a cadaver is the flow of energy. When you die. All of the structure, you know, the physical stuff remains as is, but energy stops flowing. If you stop breathing, if your heart stops beating, energy flow stops, and then energy transformation, therefore, can't happen. And then that's what we call...

death and then the mind dies right like you you don't have an experience anymore and um so the flow of energy i think it has to be the the basis not only of life which we know you know to be to be correct but also the basis of human experiences and what we experience as energy

We think about energy. We crave energy. And we know and the way we talk about, you know, this person is really good energy or this thing, you know, really energize me or, you know, had this great idea. Your friend was telling you, I had this great idea. I'm buzzing, man. Like, what's that? buzzing thing it is a real experience and uh most people will have you know had the the experience of

feeling really excited about something, right? A new idea, a new person, and then, you know, you have butterflies and, you know, there are emotions going on in your body. I suspect emotions, the best kind of first principles definition of an emotion is energy in motion. And we can talk more about what we experience in terms of energy, but I think it's pretty clear we don't experience energy per se. Like you don't have a direct experience, an empirical...

you know, access to how much fat you have in your body. Like there are hormones that communicate and, you know, how much energy is in your liver and, or how much, you know, heat is in, you know, something, what you feel, what you experience is a change in energy. When energy moves, you feel that, right? And I suspect that's what emotions are. There's like a movement of energy, something shifts, and then you experience that. A bit like if you're in a car and your eyes are closed.

and you're going constant speed, right? Kinetic energy. You have no way of knowing from first experience if you're going at 100 miles an hour, 10 miles an hour, or if you're standing still. These are very different energetic quantities, right? The kinetic energy. What you do feel is acceleration and deceleration. You feel the delta in energy.

The change in energy, acceleration, deceleration. Same with temperature. If you touch something and it's body temperature, the same temperature as your hand, you don't feel it. You don't feel, you know, room temperature or body temperature. What you feel if you touch something that's cooler than your body, what you're feeling is not the temperature of what you're touching. You're feeling your temperature leaving your body.

Right? It's the heat of your body leaving through conduction towards this. And then that's what you experience. And if you touch something that's hot, you're not feeling the energy of the thing. You're feeling the heat that's coming into your body. So you feel that delta and that... change. And that's how human perception also works. Like, you were able to see colors to see light, you've studied the visual system a lot.

You know, fundamentally, the ability of the eye of the retina to perceive, right, to sense light requires that you bring photons, right, that are beaming from... whatever source, short, long wavelength, you need to bring them into stillness, right? You need to resist the flow of photons. And then, so you change the speed of the photon and it's that change in energy.

You get kinetic energy, speed of light, and then boom, when the delta V, the change in speed happens, this is when you can trigger a calcium. release and then molecular series of events and action potential. And so in order to see, you need to resist the flow of photons, right? You need to resist, you know, energy movement. And then that triggers a transformation.

Same for hearing, right? We hear and I hear your voice because my eardrum resists the pressure waves that you're producing. So your energy is being channeled and projected through. through the air as sound waves, another form of energy. And then I'm feeling you, right, through your energy that's carried through the air. And then because my eardrum resists the pressure wave that you're producing.

And then it's that resistance, right? And that change at delta, again, in speed, by resisting the sound waves coming from you, by resisting your energy, now I can perceive them. And then there are little ossicles in the ear that transmit what used to be pressure waves into now mechanical motion and then into like fluid into the inner ear and then the cilia that move and then ions that come in, then eventually they get transformed into electricity.

So, again, it's one form of energy. Pressure waves turn into electricity. And then the brain uses electricity as a form of energy. There are many, right? But that electricity is just so amenable to... computation, processing, and integration. So once you have this common energetic language for sight, for hearing, for touch and smell and taste, then you can integrate that. We perceive energy.

transformation and change in energy. We don't perceive energy per se. I'd like to take a quick break and acknowledge our sponsor, Helix Sleep.

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Years ago, a colleague of mine who unfortunately now has passed, stopped me in the hallway at Stanford. This was Ben Barris, my postdoc advisor, later my colleague as a faculty member. He said, why do we have so much less energy as we get older? And I said, well, that's probably not a concern with you, Ben. I mean, he was known for having tremendous amounts of energy. He probably only slept four or five hours a night. But in any case,

I said, I don't know. And he goes, how come no one's working on that? Like, why are we working on all this other stupid stuff? And I won't tell you what he listed off because some of it was stuff in his laboratory. And I said, well, that stuff's interesting too. He goes, but nothing is more interesting than why we have less energy as we get older, except perhaps why it is that the brain can't change as readily when we're young as opposed to older. You said something.

Very important to underscore and that I'd like to get into a bit more, which is you said, you know, your partner said, energy is the potential for change. And you mentioned emotions, they stir us.

And that that feeling, especially a positive anticipation, is so much of what we live for. In fact, the signature feature of major depression is lack of kind of any idea that they're... is a future worth living into. Apathy. Apathy, et cetera. Whereas vitality and excitement and everything good about life is about wanting to know what comes next. So if we take a... biophysical to cellular to psychological set of steps here we would say that somehow energy is converted into this internal

vibration, which we call emotions, that let us sense, physically sense into a future. Could be even a negative emotion, but it still senses into a future. And then you give this. example, very dramatic example, but I believe appropriate of a cadaver where all the material is still there right after death before it degrades, right? But...

It can't move, and therefore there is no future. Period. It's a very different way of thinking about death. So let's talk about psychological energy and physical energy that we call vitality. And if you would, it's just a bit of a challenge, but could you perhaps use that as an opportunity to teach us about these incredible organelles that we call mitochondria?

I use a slide often as an opening slide when I give presentations to academics or non-academics, which is kind of a mitocentric view of the world. right like at some point we realized that the earth was not the the center of the world and then we switched over to a different form of a different you know model of the universe so my sense is we need to do something similar for In biomedicine, we still have, I think, in most people's minds, especially the older generations, a very gene-centric.

you know, nucleus-centric view of biology, that the genes are there and then central dogma, right? The genes drive RNA, drive protein, and then drive phenotype. And we know that that's not the full picture. And there's a lot of end phenotypes.

For example, in genetically identical mice, right? They're mice that all have the same genome and some are like very anxious and some are super chill. It can't be encoded in the gene somehow. We found recently that actually there are differences in mitochondria. And part of the reason why these animals behaviorally are different, maybe half of the variance, half of the inter-individual differences, what makes

One mouse, super chill, and the other, the brother, the sister that is genetically identical, very anxious, has to do with energetics in some way. So I use this. slide to convey this mitocentric perspective. If you want to have a copy and show people, I'm happy to share this. And one way to understand this is energy comes into the organism. as food, we eat and we breathe to fuel our mitochondria. So the reason you breathe...

It's to bring oxygen into the body. Most people know this. And then once oxygen is in your lungs, it goes into your blood, and then it goes to the heart, and then the heart kind of, boom, distributes this, you know, across the whole organism. And then when oxygen gets to your big toe or to your muscle or to your neuron and your hippocampus or some brain region, what happens is the oxygen enters the cell. And then once it's inside the cell, it looks for mitochondria.

It looks, I mean, it's attracted by a concentration gradient. So that's the mitochondria is where oxygen is consumed. And then when mitochondria consume oxygen, they basically create a downhill slope for oxygen to kind of be attracted to that. So you breathe.

to bring oxygen to your mitochondria, and you eat to bring electrons into your mitochondria. And what happens there is this beautiful sequence of reactions where you have electrons from... that were initially stuck on food by the plants, you know, taking solar energy.

to stick electrons onto carbon, and then you make hydrocarbons, and then that's, you know, glucose or starch, and then oils, lipids, everything that's good fuel for mitochondria. Those things, the food and the oxygen converge inside the mitochondria. And then finally... the electrons that were, you know, ripped off as CO2 is broken into oxygen and are reunited in your mitochondria. And so your mitochondria actually make water.

uh and and and then release co2 so that's the they close the life cycle that you know, we have with photosynthesis. Photosynthesis makes oxygen and food, and then our mitochondria brings those things together, and then they release water and CO2, exactly what plants need. So it's this beautiful cycle. So when mitochondria do this, is basically feeding unpatterned energy into the system. And it starts with the mitochondria the same way that if you feed electricity into a Morse code.

You feed electricity. It's unpatterned energy like food and biochemistry is to your body. And then by pressing and releasing a little lever with a specific pattern, what you're doing is you're patterning... electricity which means nothing it's just you know raw current and then you pattern it in something that means something short beeps long beeps and then you can spell stuff you can communicate information right so you're creating information

out of, you know, by patterning in time, right? By patterning electricity. So mitochondria, the way I see them is they're kind of an energy patterning system. And we've called them the mitochondrial information processing system. for that reason. Should we think of them like a little Morse code lever? I think it's a decent, you know, analogy for, you know, part of their behavior, part of what they do fundamentally. They take raw energy and then they pattern that energy into...

This perhaps is why I've heard you say that we should not just think about mitochondria as the powerhouse of the cell generating more ATP. That is true, but it's also true that... They're controlling the flow of energy in a very detailed way. Correct. And they're controlling the flow of energy, but they're also controlling the transformation of energy, right? The electricity can be...

converted, transformed into all sorts of different messages, signals, right, with your Morse code, depending on the needs, depending on the state, depending on the person pressing, releasing the lever. And sometimes the organism needs a lot of ATP. if you're a mitochondrion and you live in the heart and your job is to make atp a lot of atp and then there's side jobs if you're a mitochondrion in the liver your job is very different and you're a very different kind of mitochondrion

Well, let me ask you this. I think you just answered the question, but are there different types of mitochondria? Yes. How does a mitochondria in the liver versus in the brain versus in the heart know to take the energy that it's transforming and pattern its output so that... heart cells can do what heart cells need to do or liver or brain. This seems like a very important issue. Is it possible even that the mitochondria in these different tissues are fundamentally different?

organelles and we should probably define what an organelle is for people yes yeah organelle is the the technical term uh for an organ of the cell uh and the cell typically is represented as this you know skin and then inside the skin is the cytoplasm the big soup and then inside the soup the cytoplasm there's a bunch of little organs that allow the cell to do all sorts of

things and perform its activities and replicate and so on. Mitochondria is one of those organs. And their purpose is to process, transform energy. And one of the ways in which... Transform energy is taking raw energy from biochemistry, the food you eat, empowered by oxygen to flow those electrons and then making, building a charge and then... powering this beautiful rotor. Some people might have seen this. It's kind of a rotary, you know.

engine kind of thing, a turbine. And then when mitochondria build their membrane potential to become charged, they use that charge to power the rotation of this turbine. And then as the turbine turns, it converts ADP into ATP. So now you have conversion of biochemistry into electricity and electrochemical jars in the mitochondria back into biochemistry, ATP. What's in the backdrop of all this?

of course, is that all of this self-organizes during development. Yes, the genes are the blueprint, but this is all built up from scratch. Probably a tangent for another time.

heart cell know to produce a lot of ATP versus a liver cell? And of course, it's coordinated in time with sleep and circadian stuff, but how does it know or does it even know I'm a mitochondria inside a heart cell and the amount of... energy I need to transform is X. Yeah, how does a mitochondrion, or singular is mitochondrion and multiple is mitochondria, how does a mitochondrion in a heart cell know that it needs to be a cardiac mitochondrion?

Right? Is that your question? Yeah. Is it genetically different than a mitochondrion from the liver? No. They're genetically exactly the same. And that's another... kind of punch to the gene-based model of biology, how could it be that every cell in your body is genetically identical and the mitochondria have their own... genetic material. We all have our mom's mitochondria, which is really beautiful. 100% of our mitochondrial genome is from mom. Is that true? Correct. Okay.

And there were a few papers a few years ago that said, oh, no, look here. There's this one case. This one kid or these two kids that have paternal father mitochondria. Turns out it was like a mistake in the sequencing. So mothers are.

truly always right yes power to power to mothers people will be thinking and i'm also thinking does that mean and of course there are lifestyle issues but does that mean that if we were to look at the quote-unquote energy levels of mom versus energy levels of dad that what better predicts the energy levels of a kid is the mother's

sort of baseline levels of energy at a given age? I don't know of studies that have asked that question about like subjective energy or like the energy to do stuff and which we can, I think we'll talk more about. But people have looked at... Other more tractable, which is what we do in biomedicine, we take things that we can measure objectively or like, you know, run on a gel or sequence or, you know, objectify with a biomarker in the clinic. People have looked at longevity, right?

Are you more likely to live long if your mom lived long or if your dad lived long? Turns out the heritability of longevity is more maternal than paternal. Are you more likely to have a mental health disorder?

or to have parkinson's or alzheimer's if your mom or your dad had it some evidence say it's more maternally inherited than paternally inherited so it could be that Part of your ability to live a long, healthy life or your risk or your resilience to those disorders really are conveyed or carried by mitochondria, by your ability to...

to transform energy. And the reason why through evolution So uni-parental inheritance, you get your mitochondria from a single parent, has developed, most people think, is because there needs to be a really close metabolic energetic match between the mom and the baby. Right? Like the baby comes out and then if the mom has like a certain type of metabolism and we're all different, I hope we talk about like how different we are energetically, metabolically.

So we're all very different. If the baby that was born was like so metabolically different than the mom, there's a chance that there would be a mismatch, right? And then the mom wouldn't be able to support through breastfeeding historically. That's how babies survived. And that would be a catastrophe. So it's probably a good system to have baby metabolism match pretty closely.

because they have the same mitochondria as their mom, to mom metabolism. So that's, I think, a loose hypothesis, but it makes a lot of sense. It does make a lot of sense. Every mitochondria you have in your body...

like the brain mitochondria, neuron mitochondria, astrocyte mitochondria, whatever your favorite cell type is, your heart mitochondria, liver mitochondria, muscle mitochondria, they're very different. And now we have a new method. There's a wonderful scientist in our group, Anna Monzel. who's developed a method to profile different types of mitochondria. We call this mitotyping. The same way that now in neuroscience or in immunology, it makes no sense to talk about a brain cell.

or like an immune cell. If you're a self-respecting immunologist, you know your cell types, and there's at least 30 different types. So I think we're at this point in mitochondrial science. where we need to adopt a similar level of specificity. There are different types of mitochondria. We call those mitotypes. And they emerge, all of them, from the same mitotype in the egg.

The egg that the mother carries and releases from the ovary, there's about half a million mitochondria in that egg. And then those mitochondria, there's a single type of mitochondria in there. And then when it's... fertilized, development happens in this beautiful process. And through that process, as the heart starts to form, the brain starts to form, the muscles start to form, the mitochondria differentiate.

And then you end up with different types of mitochondria that are adapted and matched to the different demands of cell types, of organs. And one way we think about this is I think it's... it makes a lot of sense to think about mitochondria as social organisms. And there are multiple features of mitochondrial biology that obey what behavioral social scientists classify as social.

You know, if you study ants, for example, there's like a few rules that we know ants are social creatures because they form groups, right? And there are different types. They divide. There's division of labor. You have worker ants that, you know, work really hard. And you have warrior ants.

that are like really chubby and like they're here to defend the hive. They like to fight. Yeah, exactly. So those two types of ants, you look at them side by side, there's like this little flimsy, super like active worker ant and then this like chubby. and genetically, they're identical. They have the same genome.

They came as, you know, a little larvae from the, you know, the queen. But their morphology is super different. Their behavior is very different. But through development, their cues that, you know, are... applied to the different larvae and then they end up becoming a worker or a warrior. So the same kind of thing happens in mitochondria. So there are different types of mitochondria, like the two types of ants. There is division of labor. There's some mitochondria, for example.

in the muscle that are at the surface of the muscle, like just underneath the sarcolemma, the skin of the muscle cells, and then their mitochondria are inside. We are where the actin, myosin, the contractile proteins happen. Subsarcolemal mitochondria and intermyofibular mitochondria. Two populations. Their proteome is different. Their molecular composition. of those different types of mitochondria are different, their functions.

ATP synthesis, reactive oxygen species production, their ability to handle calcium and release calcium is different. Their morphology is very different. So even within one cell, you get this division of labor and... differentiation of mitochondria and in every cell mitochondria have a life cycle. New mitochondria are born and old mitochondria die out, which is what happens in social creatures.

And there's a few other features like this that I think make mitochondria social organisms. And once you start to think about mitochondria as social creatures, then you understand maybe a little better why they need to fuse with one another. And if you ask Google, what do mitochondria look like? Or chat GPT or whatever. It shows you always the same kind of images. It's like a little bean.

You brought one as a gift. At one moment, I thought they might be brass knuckles when you first handed them to me, but it's a mitochondrion with the cristae of the mitochondria. There you go. It usually looks like this, but you're saying in reality, there'd be many of these closely fused to one.

Yeah. And when they fuse, you get these like bean or kidney shapes or peanut shape, whatever your preference is, that fuse with one another. And then they form these beautiful filaments. So if you're lucky enough to work in a lab...

that has one of these cool microscopes called confocal microscope or light sheet microscopy. And then you can make the mitochondria fluorescent. So you put a dye in the dish and then it's a little fluorescent molecule. It goes inside the mitochondria. It's attracted by the big...

uh charge that mitochondria have uh and then you turn off the lights look down the eyepiece and then you see this beautiful like filaments you know mitochondria moving they move pretty slowly and interestingly they're just at the edge of human perception of like how quickly we can perceive things to move. So they move like, you know, barely fast enough so you can see them. And then they kiss and then confuse completely.

You can invite everyone to your lab to see this, but that's a lot of people. You'd be very busy. We'll put a link to a video of this. We're building a web page called Mito Life, which is to help people understand themselves energetically. and through the beauty of mitochondria. And there are all sorts of different types of mitochondria that move differently. And when the mitochondria are not healthy and if they can't flow and transform energy properly, they start to look really weird.

It occurred to me that, you know, for the longest time, I'm 50 now, so I can say for the longest time. For the longest time, we heard that if we want energy, we need to eat, right? Of course, we need to sleep. But we need to eat. And every kid learns. You're consuming energy so that you'll fuel your body. There are all these discussions. You should eat meat. Don't eat meat.

I believe you should eat some meat. You should eat some vegetables, some fruit, et cetera. I think you should be an omnivore. Some fats. Yes, that's my belief. But we all understood that. But then at some point, probably about 10 years ago, It became clear to people that just consuming more energy didn't give you more energy. It was an obvious thing. But it's now abundantly clear. And based on what...

You're saying it should be clear to everyone that the issue is not lack of energy going into the system. It's that the transformation of energy that occurs in mitochondria somehow is not happening correctly in people that are obese. or in people that are eating and feeling lethargic. And of course, there's blood sugar aspects to this, and we could discuss all of that, and we won't because that's not the topic for today.

I think if nothing else, if people can just understand that they have not just these powerhouses, but these power plants within their bodies that are transforming the energy and the mitochondria are central to how the energy is transformed and distributed.

on an organ by organ basis, I think that would be a helpful concept for people to get into their mind because people are talking about mitochondria all the time. People are talking about and hearing about nutrition all the time. And so often we just think about calories.

And, you know, everyone knows that, you know, calories a unit of, you know, heat off, but when you burn a given food and we learn this stuff, but it doesn't transform into good health practices. But I think nowadays people are starting to get a sense of, how their bodies work. And you're adding a lot of important detail and aspects to that today. So I just wanted to frame that up. If you have any reflections on that, great. If not...

It was just a point that came to mind that I think might be useful. Yes, it's so important. And we are energy. Fundamentally, we are the flow of energy through this biological infrastructure that we call the body. you are not the cells or the genes or that thing. You are much more that energy that is flowing, which is why when the energy stops flowing, you are no longer.

When you die, all the physical stuff remains, but you no longer have an experience. You no longer exist as a person. The way I think about this is rather than thinking in nouns, think in verbs. And I think as biologists, when we teach biology, you have to teach some nouns, some names of things. But if you can get people to understand the verbs as concepts, it's worth... a gazillion nouns. And so I think people thinking about themselves as a verb state, of as energy...

transformation being. It sounds so mystical, but it's not mystical. It's biochemical. It is. I think could be useful. Along those lines, I do want to talk about this recent paper that you published. which essentially, my understanding is that looked at different brain areas and found that different brain areas have different concentrations of mitochondria. And we know that...

Different body areas and different organs have different concentrations of mitochondria. But I heard you say someplace, and this is such a beautiful, sticky topic, as they say, that perhaps the things we do in life... maybe lift weights maybe study biology maybe play the piano maybe some combination of things

will enrich the mitochondria, these energy transformation sites, in particular organs and areas of our brain more than others. And so we really become what we pay attention to. We become enhanced.

for what we do. And that makes sense at the level of endurance runners run and their muscles become, and everything becomes optimized for running. Weight lifters, something else. But in the brain, this gets very interesting. This means that if we... read poetry for instance or study biology that the areas and circuits of the brain that are responsible for that

in some sense, become better at doing that. And I think this is a very important topic because it really gets to the essence of who we are as individuals based on our choices of what to do and what not to do. So with that as the backdrop, if you could tell us about this paper and tell us about what you think about these findings and what they might mean, I would love that. We flow as energetic processes.

To your point, we are transformative processes. We transform. We flow. We are the energy that flows. And the more you direct energy to one area, if you go to the gym and you do bicep curls, you're resisting the flow. of energy while you're contracting and then you do this a few times and then when you let go, you get like blood flow, right? Energy flow through the system. And we know exercise training is a beautiful example.

train to run a marathon, for example, you can double the number of mitochondria in your muscles. Double, right? And... My understanding of this is as energy flows through the existing mitochondria, you're basically bringing energy into that system. And then the biochemical energy gets transformed into molecules, into metabolites, and then eventually into proteins. and then structure gets created as energy flows. So it's the flow of energy. First, you resist it.

We call this energy resistance. And then when you let go of the resistance, that's when we build. That's when we grow. That's when Arnold Schwarzenegger said muscles are torn in the gym.

They're fed in the kitchen and are grown in bed, I think. In an Austrian accent. Yes. So, yeah, if you direct energy towards... a muscle right then one way to direct energy is to resist the energy flow and then to to let go and that's what exercise fundamentally is right you resist the energy flow and then you let go when you resist energy too much it feels uncomfortable which is

burning pain of and then when you let go is when growth and, you know, building can happen. And we know the same thing happens like everywhere. This is this is not like a mysterious thing of the muscle and like of exercise. you know, physiology. This is a fundamental biological principle. If you flow energy in one area, then it will grow. It will, you know, get better. It will get more efficient.

And if you block energy flow to one area, like you block blood flow, for example, or you get an accident and the nerve gets, you know, damaged, then the muscle doesn't contract anymore. You're basically blocking the flow of energy there. And what happens? Atrophies. Atrophy is a normal movement of life when energy flow decreases. And if there's no energy flow, there's no purpose for that structure. If you feed, if you stimulate that structure, be it a muscle.

or brain circuit, right, a brain network or brain area, then naturally, you know, that area should grow and build. And what we know happens in the brain and also happens between different organs of the body is... there's kind of a competition for finite energy resources, right? What you said earlier, like you can't just eat more to get more energy. Now we know very well, if you overeat, right? You eat more than your body is actually...

flowing, consuming in terms of energy, transforming, you get sick. Like if you can, you put on fat, which is a good adaptive. coping mechanism to eating too much. But then eventually the system gets overwhelmed and then that hurts the mitochondria and it hurts, you know, cells to become insulin resistant. And so there's all sorts of consequences to eating too much. You cannot...

eat more to get more energy. And that is, I think, still scientifically a very big mystery, right? That why can't we just ramp up our energy? consumption energy transformation and then like sleepless and you know work out three hours every day that even like professional athletes who devote all of their energy to you know building muscle mass building skills or you know building aptitudes there's a limit to how much you you know you can eat uh and they're

We don't really know why that is, why there's a limit to that. And so the body operates an economy of energy. You have X amount of energy. You can push that up. you know, over short periods of time. Like if you start to work out and you're a cyclist, you do the Tour de France, right? Like three weeks, you're going for like 5,000, 7,000 calories a day.

You do this for three weeks. There's a reason why the Tour de France is not four weeks and five weeks, right? There's a cap and there's beautiful data showing that the longer the event, the athletic event, the lower the max output per day. And if you look at that curve, you know, the first point, max power output you can develop over 10 seconds is what you see in the 100 meter sprint, right? And then you get the...

400 meters, and then it goes down. And the Tour de France is, you know, marathon is here, Tour de France, three weeks is here. Then you get like crazy run across America, multiple weeks. And then at the very end, nine months, pregnancy. And it costs energy to grow a human being. And some of the data suggests that when you grow a human being for nine months, the woman is basically operating at the max of her capacity if you integrate over a nine-month period.

Do pregnant women accumulate more mitochondria or the energy demands are entirely for the mitochondria of the developing fetus? That is a good question. We know certain brain areas grow during pregnancy. The brain remodels, exactly.

uh there are different demands right as a mother if you're pregnant now you need to start to care about different things maybe it's uh adaptive to start to think about the world a slightly different way and it's not just just about yourself and um so there are certainly And even long-lasting brain changes happen in the woman's brain. So this economy of energy between organs is likely what explains if you're a young woman and you exercise a lot, you lose your menses, right? Amenorrhea.

And this is not because the reproductive system is broken or because the ovaries are sick or something like that. The best explanation we have is there's a shortage of energy. Like you're pushing and driving all of your energy budget towards your working muscles, towards making more mitochondria in your muscles. And there's no more energy to fuel reproduction. I have a practical question related to this.

I've always wondered why is it that when we're coming down with a cold or a flu or some sort of other infection that... There are a bunch of processes that make us more lethargic and tired. And these are very adaptive. And we know we need to rest. But it's not just about getting sleep. We actually need to slow our circulation down. We need to rest. And there are all these theories, you know, about...

you feed or starve a cold or flu. And I covered that in a different episode. I will put a link. It's not straightforward, but follow your appetite, stay hydrated, keep your electrolytes up and so forth is the short answer. Is it that the immune system needs more energy and the body as a protective mechanism, as an adaptive mechanism is saying, slow down everything else and devote yourself to.

healing to fighting this infection as opposed to spending energy even walking up the stairs as much as you typically do during a day. Is that the idea? Yep. I think that's the best model we have. And I had a personal experience of this over a New Year's a couple years ago where I could feel I was, you know, coming down with something before the, you know, New Year's dinner.

And so it ended up being a pretty short night. I went to bed early and that night was terrible. The next day I was so, so off. And I was, you know, starting to work on the book Energy. And then I thought, oh, this is such a cool. opportunity like now i'm experiencing i'm feeling drained right like i'm in bed everything hurts and then i thought

I should be writing about this, right? And then I thought, just the thought of grabbing my computer, then I shouldn't cost more, doesn't cost a lot of energy, just wiggle my fingers on the keyboard. But there was no drive. I stopped caring about stuff that I usually care about, right? Everyone has experienced this when you're really sick. Motivation, right? Zero. My capacity to be the best human being that I am and to be kind. A little diminished. Just like, I was just trying to fucking survive.

And what we know in terms of biology and mitochondria and energy that happens when you're fighting something like this, the immune system costs a lot of energy. So I think the best model interpretation we have of sickness behavior is what you were describing, the technical term, is you feel sick, right? And you don't want to move. The body, you feel cold.

which then forces you to put covers or, you know, to dress, to avoid cold environments. It hurts to move your body, like to contract muscles. And like there's alladenia, right? You become more sensitive to pain. All of these things likely exist in service of conserving your precious energy budget. And even not eating, right? Like follow your appetite, yes. And if you, you know, eating costs energy.

Nothing in biology is free. Everything costs something. And if you eat food, now you need to masticate. You need to like have peristalsis. You need to have gastric acidification movement, you know, secreting digestive enzymes and be some bile. The orchestration of digestion is pretty expensive. It's like 10, 15% of your daily energy budget. So that's 10, 15% of your daily energy budget. If you're running like a limit is a lot.

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You mentioned that if women exercise beyond a certain threshold, they stop menstruating. And that it's because there's not enough energy, essentially, to menstruate. One idea would be, well, if you just eat... enough then you have enough energy but we have to think in verb states not absolutes and so what i'm realizing is that while one needs sufficient energy input in the form of food and this could also be true for the example of being sick

It's necessary but not sufficient because the mitochondria are doing two things. They're transforming that food energy into bodily energy to menstruate or to move or exercise or think or care about a book, et cetera. But part of their job is not just to transform the energy, it's to distribute the energy. And so you really need two conditions. And, you know, I'm not a computer scientist, but I know enough about programming, you know.

and engineering that, you know, this concept of an and gate, you need sufficient energy. So coming into the system. And you need to be able to distribute that energy properly in order for something to occur. It's an end gate. You need both things, basically. So I now and forever going forward will think about mitochondria.

as not just energy production, but energy distribution organelles. Yes. Thanks to the way you described it. And now it makes perfect sense as to why when I'm sick, if I'm not hungry, I'm not going to force myself to eat provided I have enough body fat stores.

You know, I need to eat eventually, but whatever weakness or fatigue I feel is probably in that situation where I don't have an appetite is probably not a lack of caloric energy driving that fatigue. It's that my body is saying, you know what? You're better off. just not having me shuttle

that food energy through you so I can shuttle your immune cells to the proper place. And this is when people say the body is smart. There's an intelligence to the system. I think that's true because with our brains, we think, oh no, I'll just cram more energy into it. You need to eat. You need to...

No, maybe not. Whereas if I do have an appetite, I don't care what people say about feed a cold, starve a flu, or, you know, starve a flu, feed a cold. I'm just going to do what my body tells me to. Yes, yes. And I agree. The body is wise. Animals who don't have a very... other non-human animals like your dogs they don't have a mind to distract them from you know living

an alignment with their energetic states. So when they're sick, the immune system, just the amount of the part of your budget that gets consumed by the immune system. you know, expands, right? So this energy, this extra energy needs to be stolen from somewhere because you can't eat more to have, you know, infinite energy. So where is that energy coming from?

So not contracting your muscles because you feel in pain is a good way. Not having to thermoregulate because you cover up, another way to conserve energy. And then stopping to care about stuff, like becoming asocial and apathic. All of those features of sickness behavior or energy conserving strategies and not eating, if you can... have like free 10, 15% of your energy. Now you can allocate it to your immune system. That is a very good strategy. Most people walk around with multiple weeks.

if not months worth of energy, right? Like under the skin and our love handles. The record actually for not eating is from this Scottish man, 382 days. Was he fat when he started? He was very fat. Was he fat when it ended? He lost, how much he lost? Like 250 pounds, I think. That's a lot of stored sandwiches. Yeah. So most people can eat, can go a full month without eating.

This maybe goes back to what we talked about earlier. Like we don't feel energy quantity, right? Like if you close your eyes and you feel your energy, like you don't... feel how much fat you have on your body, how much glycogen you have in your liver or, you know, in your muscles. What you feel is the transformation of energy. The neural energy. Do you want to do a little experiment? We can do a little experiment to feel our energy. Definitely. Yeah, okay. By the way,

A tenured full professor at Columbia School of Medicine just said, do you want to do a little experiment to feel your energy? And we both closed our eyes, which tells you that it's definitely 2025. Good things have happened in the world. both closed our eyes and kind of stopped moving our bodies, which is kind of what you do if you want to meditate or something like this, is because it turns off the noise. Right? And the...

If you want to survive in a dangerous physical world, you need to be aware of like stuff that might hurt you, right? Or kill you. And feeling your body like proprioception and all of this needs to be very high level. It needs to be prioritized. whatever introceptive signal there are. There's some introceptive signal, that's what we'll feel into, that can overcome that. But just not moving the body, closing your eyes, it kind of helps you to tune into your energy.

And I suspect there's a lot of value there. We'll talk more about some incredible results about meditation and restoration of energy. Can the audience do this along with us, provided they're not driving? Yes, yes. Okay, great.

So to do this best is you're sitting comfortably and you can close your eyes if you want to. I think that helps with the process. We'll take one breath in and then we'll... will hold her breath for a little bit so breathing in breathing out and you can breathe out all the way all the way down and then hold that breath And for the first few seconds, it's generally not too uncomfortable. But then as you hold this, feel into your body, to your belly, into your chest, into your head.

What's the effect of not breathing? And then you start to feel maybe this urge to breathe and this desire to bring oxygen into your body, to your mitochondria.

And when you need to, you take a breath and you can open your eyes. If you can hold it longer, you do. What did you feel? So when I went to the full exhale and held my breath, my... what we geek speak what neuroscientists call interoception my perception of things from the skin inward became more salient and i could feel my heartbeat uh more and more um and then

it didn't speed up but i could just feel my heart beating i was more aware excuse me of my heart beating and then i as the impulse to breathe started to kick in uh you could feel a bit of ramping up of it's not anxiety, but it's a sense of urgency, hardwired, fortunately, sense of urgency. And then with an inhale, there's a relaxation of that.

And there is this sense that energy moves out from the center at that point. Like you'd feel more of your body. Because I think anytime we don't have air... our brain goes to, how do I bring air right here, right now? You're not thinking heartbeat. You're thinking, get air. Something of that sort. Yes. I think... If you do that and the urgency, right, the anxiety, the stress, or this, you know, it feels dangerous, right? And I think to many people.

Dying by drowning or suffocation is one of the worst deaths. So why is that? What is that sense of urgency, of anxiety? It's CO2 building up in your blood. CO2 is the product that mitochondria release as they transform energy. And then when CO2 builds up, it means oxygen is getting depleted. If oxygen gets depleted, the electrons from the food you eat can no longer flow.

If there's no oxygen at the end in your mitochondria to accept the electrons flowing, you stop flowing. So you, as a movement of energy, are at risk of ceasing to exist. Not being able to breathe, right? Being out of breath is an existential threat to your energetic self. Without getting into the details I've talked about in another podcast, I had a scuba diving accident.

A few years ago, 2017, ran out of air in a bad situation to begin with. And I'll tell you, the sense of urgency is very immediate. Fortunately, I didn't end up with any PTSD from that. It obviously worked out okay. I'm sitting here and talking. But now I understand why. And I never did this to another kid, nor did anyone ever do it to me. But there's this.

joke that kids play on one another where their friend is coming up from underwater and you're ready to take a breath. That's why you come up from underwater. And if someone holds your head right at that point, even though it's just a moment, the sense of urgency that kicks in is very...

intense and very, very fast, which speaks to just how hardwired these circuits are. Because at that point, presumably, there was enough air to stay under for another five seconds or whatever it is. But when we anticipate getting oxygen and we don't... There's a big increase in stress. Energy goes straight to whatever areas of the brain, amygdala and other areas, presumably, that are like, this is a bad situation.

Anything and everything becomes about resolving the situation. Yes. And that's because we are energy. We are the flowing energy through the system. And if energy... starts to stall it just feels so uncomfortable we have to have evolved to feel this if something is making your energy stall like there's not enough oxygen around you need to get out of there

And you need to have this instinct to survive. So what's trying to survive is not like the physical body. It's this flow of energy that's being threatened. Right? From lacking oxygen. Many times already you've talked about the flow of energy and that concept, I think it's going to be threaded through as we go forward. When you hear about practices like Tai Chi...

Or when you hear like in the martial arts where people are taking other people's energy and, you know, converting. And this is not just a thing of like Aikido, but the notion that like if you box, you learn that you.

You're not just hitting with your arm and your shoulder. You have to keep your feet planted. You're pulling from the floor in some sense. You're transferring the energy. You're actually pushing back against the floor, and then it's coming up through your body. People talk about the fascial slings, you know, when people run.

bazillion different variations on this, but it's all about this concept of flow of energy. And I find that so much of what we find incredible when people dance, when people- sing when people do incredible athletic feats or channel everything they've got into something, this channeling of energy, is the human animal deliberately channeling all their energy in the form of practice. into something. In many ways, we love that, even though by definition it creates a very lopsided person.

And I'm not trying to get into the psychology of this so much as I want to go back to this notion of our brain areas having different amounts of mitochondria, probably from birth. But then if we play soccer and we like math and... pottery, we get a different brain than if we like reading and theater and movies and we'll exercise, but we're not too crazy about it. You know,

If we exercise, our brain works better, we've heard. But there's also the notion of the person who just spends all their time exercising, and their brain doesn't get better. I'm being gentle there. And I like exercising, and I like thinking. Is there a trade-off? Is there a trade-off? Yeah. Because I believe in staying fit and staying healthy and living a long life, but most people are not competitive athletes.

Most people don't want to be the strongest person in the gym or the best runner. Most people, I believe, and I'm one of these, I want to be strong enough. I want to have endurance. I want to have some speed, but I want to be able to think. I want my mitochondria balanced across all my systems. My girlfriend would say, well, you're a Libra. Of course you do. But I'm saying I want it because I want to be able to lean into a lot of different aspects of life. I don't want to become the atrophied.

in one area and hypertrophy to some great extent in some other area human. So what are your thoughts on these through the lens of the results that you recently published? Is it a trade-off? I don't think we know. Exactly, but we did a study recently that points to the fact that there might be trade-offs between different systems. Sorry, meatheads. No, I'm just kidding. I love working out in the gym, but you have to read too, you know? You know, we tested the hypothesis.

is that if you have more mitochondria in your muscles, you also have more in your brain and in your heart and in your liver and in your skin. And the result is that's not the case. And you, Andrew, I think you seem to derive a lot of fulfillment. you know you live up to your full potential when you can do all of these things right and you're a great communicator you're a great integrator you know the kind of thinking you do is like this this beautiful integrative thinking uh which is

Which might be what has led you to do what you do now, right, with most of your time. Because this really taps into your strengths. It really moves you. I suspect, energetically. I enjoy it. You enjoy it? What does that mean? Enjoyment is kind of an emotional state, an affective state. It's an energetic state. We're all different energy transformers.

Right? Like you transform energy and you have this ability to do what you do. Other people have very different skills, right? And gifts. I think we were born with something that doesn't seem to be fully just encoded in people's genomes. genetically identical twins that have very different aptitudes and personalities. And we don't know where this comes from. And then we are fed, we're moved and inspired by different things. And when people seem to...

Follow that, it appears to bring them energy. And what this means biologically, devil of mitochondria, I think our research is starting to point in a direction that says if... You're engaged in things that bring you purpose and fulfillment. There's another study we did. We asked people, our colleagues in Chicago, asked people before they died, how much...

sense of purpose do you have in your life? How meaningful social connections, well-being, right? And then the negative stuff, depression, loneliness, you know, anxiety. And then every year they answered those questionnaires. So we knew how deep people... felt about themselves, about life, about some greater power beyond them. And then they died, gave their brain to science. We got a little piece of brain, and now we're measuring the mitochondria. And Carolyn Trump, a researcher who...

works in our group, who's a bona fide mitochondrial psychobiologist. So she asked questions between the psyche and the biology of mitochondria. So she asked, could it be that how people felt before they died? relates to the binochondria in their brain and the prefrontal cortex, the DLPFC, the dorsolateral prefrontal cortex. And what she found is that people who felt more purpose in life and who felt more connected to others and who felt, you know, well-being.

for whatever was bringing them well-being. It seemed like that was sufficient to increase the energy transformation capacity of the mitochondria in their brain. So is this because... of the experiences that they're fortunate to have or that they're actively fostering in their life that's actually transforming the mitochondria in their brain, maybe, or it's the other way around. For some reason that we don't understand, they have more of...

the energy transformation capacity in their brain mitochondria, and that is leading them to experience the world as more positive and as more purposeful and as more meaningful, right? Animal studies say it probably goes both ways. So if you tweak the mitochondria in a rat brain, you can change the behavior of that animal.

from more submissive to more dominant or from more dominant to more submissive. Beautiful work by Carmen Sandi at EPFL in Switzerland that showed this. And then the other way around, if you chronically stress animals, you deprive them of kind of freedom of choosing different...

you know, options, so chronically stressful things, actually damage the mitochondria in the brain. And in some brain areas, there are fewer mitochondria and they don't transform energy as well. So the mitochondria are responsive, it seems, to our states of mind.

uh and that the mitochondria in our brain can also influence our state of mind and and if if we want to talk about the philosophy of this thinking about like what's causing what maybe isn't you're really the right question to ask but what's emerging is that's relevant to your question There's a clear connection between the subjective experiences that we have, that we know from first person to be meaningful, right? Because that's what we have access to.

primarily is how we feel, how we experience the world, somehow is related to the biology of the energy transforming units, energy processing units in our brain. And maybe also in our immune system. And so we've done work in immune cells. brain tissue. And we're currently analyzing mitochondria from 5000 human brain samples. That's 10 different brain and muscle samples from 500 people. Do you have histories on these people as to how much purpose, what they did, how much life fulfillment they had?

I'm so glad that biologists like you exist. I just want to say that. Not just because you're agreeing to be a public health educator, but just it's incredible. how much things have changed in the last few years in terms of the public awareness about biology and psychology but i i have the genuine sense that with you doing the kind of work that you're doing that

No longer are we going to be talking about the Eastern philosophy of energy versus, you know, mitochondria in a laboratory at some medical school, at an Ivy League medical school. But you're merging these ideas. in real data and i think it's going to bring together ideas that have been in cooperation for a long time but didn't realize it and i think it's going to transform human health because if we think about ourselves as energy transformation beings

We're going to think pretty carefully about where we invest our time and energy. And also, I do think start to listen to our bodies more when we're feeling shut down. Like, what does that mean? Now, we can't respond to...

everything as just a, well, does it give me energy, not give me energy? Because we also have to build up some circuits to be proficient in life that perhaps are inconvenient for us to build up. But at the same time, i think there's a lot to be gained from this idea of does something give me energy does this i think people uh confuse like drama and friction with certain people it's like that's energy expenditure that's not

That's not a good transformation of energy. And you hear about this stuff now more in the psychology relationship space. People will say, you know, they're not good for my nervous system. It's so funny how neurosciences now, you know, or I just feel relaxed around them or I can.

sleep next to them so comfortably. And, you know, we kind of write these things off as like, oh, that's cute. That's kind of woo. This sounds like real biology if pushed through the lens of what you're telling us about mitochondria as energy transformation units. Yep. I think everything you just mentioned doesn't make much sense from this molecular biology lens that's really captured biomedicine. Many years ago...

50 years ago or so, there was this wave of, whoa, there's DNA that exists and there's proteins, we can sequence stuff, we can measure. uh the components of a cell and we can look at things under the microscope and we can you know scan the brain and like all of those um

assets that we were all of a sudden able to capture. It was really convincing, compelling. We built a whole research and academic science ecosystem around this. And I think as a... um by by nature this reductionistic framework pushed aside the mind right the all of the subjective experiences you know it's in your head or you know whatever all of this was pushed aside so the human experience is the most direct way

in which you can know whether the content of your life matches your energy, right? And matches what matters for you. and what you really care about. So like pushing aside, which is what biomedicine has done, pushing aside the mind and all of those subjective experience, I think has been really damaging to understanding the basis of health.

and understanding what allows some people to be healthy for a really long time and to live long, healthy lives and to live, you know, fulfilled lives. If we think of ourselves as molecular machines... like there is no way we can make sense of this and then we have consciousness you know research that's trying to make sense of of these beautiful uh this beautiful spectrum of human experience right from like i can't

get up in the morning like taking a shower is like too difficult and i'd rather die like this is one end of the spectrum and then the other end is oh my god the world is so beautiful i'm so grateful i feel inspired to be a good person And I can do good in this world. And then everything in between. And we're left now. We don't have a science of this. We've...

We've said this is not science, right? This is like psychology. This is Wu stuff. And we can't access this with biomolecular science. And I think it's true. I'm not, I don't have a lot of hope. That we will make great inroads in fully capturing the nature of consciousness, the nature of the human experience, the nature of well-being, of what it means to be a fulfilled human being that lives up to their full potential. I don't think...

At this point, that we'll find answers in molecular biology. But what I do think is that an energetic understanding of life and an energetic understanding of ourselves, right? as a flow of energy, not as the molecules and the metabolism that support this flow, but as the flow itself. I think that is kind of a point of consilience. Energy flow is the linchpin between matter.

You know, the stuff of biology and experiences. Again, we don't experience energy itself. We experience a transformation of energy. When energy flows through this metabolic circuitry. that we have metabolism is just an energetic circuitry electrons flowing not as free electrons in a copper wire but as electrons from food to oxygen through enzymes right so this thing is a a metabolic

carbon-based energetic circuit. And when energy flows through this, somehow, for reasons we don't fully understand, it feels like something, right? And emotions, energy in motion, subjective experiences of... feeling inspired and doing good or feeling terrible wanting to die like these states all live and all emerge

from the transformation of energy. Energy is kind of that consilience point where we have, you know, behaviors, everything we do in neuroimaging, right, the EEG or whatever, when we look at the brain, we're really looking at energy patterns.

If you just change how much energy flows in one region or another, you change the anatomy, you change the biochemistry, and then that gets encoded. If energy flows a certain way or is patterned a certain way, it will change how genes are expressed, right? It will change the epigenome.

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But they're offering early access to Huberman podcast listeners. Again, that's functionhealth.com slash Huberman to get early access to function. What I think has been missing in this whole landscape of health. frankly, has been somebody who understands the different levels of analysis. A great neuroscientist now at NYU once told me that a real intellectual...

of which you are, is somebody that understands and can communicate something at multiple levels of granularity. That's very, very important. So I'm very reassured by everything I'm hearing and where this is taking us. That takes us to your... Opening question, which is like takes us through mitochondria and how that affects cellular and organ and behaviors. I think what we just touched on here is like mitochondria.

flowing, transforming energy. And then that energy kind of ripples out at the level of the cell.

And there are metabolites that our mitochondria are producing. Based on the energetic state of the mitochondria, there will be more, you know, acetyl-CoA and citrate and lactate and alpha-ketoglutarate. And those are all, you know, molecular... imprints of an energetic state and then those molecules carry this energetic signature that's in the mitochondria to the nucleus and then boom they get written

down as the epigenome. And now the cell, all of a sudden, has this gene turned down, turned off, or this other gene turned on. And now the cell is a different kind of cell. because there was a change at the energetic level in the mitochondria. And then that ripples out. Now the cell, you know, experiences its environment in a certain way energetically.

It starts in the mitochondria, ripples out to the nucleus. Now the nucleus is able to make proteins like cytokines. And so cytokines in many ways are signatures of an underlying energetic state. So what we call inflammation. My understanding of inflammation is it's an energetic state. And in many cases, if the energy doesn't flow freely or with low resistance in the system...

If you're a cell and either you're running out of oxygen, right, you're hypoxic, electrons can't flow. As a cell, you know, you have this primal experience of what you experienced earlier, right? You're not breathing, you're like... i have to take a breath or i'm going to die so if you're a cell and you experience a version of this a really primal version of this you need to do something

So you call out. You call out. You call out for help. That's where the cytokines come in. Yeah. Cytokines are universal language of cell-cell communication. Cytokines are not immune. There's this fundamental way that cells have to talk to each other. Assuming that it is this repeating set of principles of energetic flow, let's get a little woo for a moment. Let's get really woo for a moment. We are in California.

And beginning to understand it's grounded in real biology. For instance, people have heard of the 27 Club. There's this, it's not a club anyone wants to be a part of, which are incredible musicians and artists who. just seem to have this incredible talent and intensity, and they die at 27. And, you know, and there, of course, certain things like music and art.

Sometimes our, you know, there's... overuse of substances and substances were almost always involved in these various cases jim jim morrison and jimi hendrix and you know chance joplin and there are others i don't know if they're all in the 27 club but i believe so and there are others But this idea that for people whose quote-unquote flame burns really hot, their intensity, you know, their charisma early on, they tend to die young.

And if not at 27, there are a lot of examples of this. If you look into these different cases... not the ones I just mentioned, you often find that there was amphetamine use. And you say, well, like, what is amphetamine and cocaine use really? Well, it taps into the dopamine system, the epinephrine system. This is definitely the stuff of energetic.

deployment and release and transformation. These are not drugs that subdue people. These are drugs that energize people. And it's as if really there was a lot more life packed into a shorter period of time and they die early. In a parallel vein, I once had a conversation with someone that I understood was a child prodigy. And he stopped me at one point and he said, no, former child prodigy. And I thought, okay, we're being...

you know, kind of detailed here. But I went and started reading about child prodigies. You know, you don't meet many adults that are brilliant. who continue to get brilliant their entire life, more and more and more and more brilliant. In other words, child prodigies eventually plateau.

They just get there a little earlier. And in some cases, a lot earlier. Have you ever heard of somebody graduating medical school at 16 and then becoming the best physician in their field, continuing into their 70s and 80s? No, people caught up. People catch up to prodigies. And so there's this idea perhaps that, you know, the allocation of energy when it's really directed in time and in space to certain circuits of the body, we see incredible feats.

I'm like, whoa. But then it doesn't continue forever. And I'm going to bring this around to this concept of longevity in a moment, but I'd love your thoughts on that. And then I'd like to talk about how... The things that all of us can do can keep our mitochondrial reservoir high enough so that we can allocate it in different directions. But just curious your thoughts about people who... Their fire burns really bright, and then it goes out early. And prodigies seem to...

channel all their energy and do phenomenal things. And we're delighted by the doctor who's 16 or the person who graduated law school took the bar at 17 or something. But then you look later and they're doing interesting things. But they're not phenomenal later in life. People caught up. There's a parallel in biology, which is how different species develop much faster.

then they reach your reproductive age much faster and then they die much earlier much you know earlier like mice for example they live like two to three years and they developed really quickly So everything is like accelerated. And there's two beautiful papers, one published in nature, one published in science on the same month in 2023 that I think shed some light on this. They ask, what controls the pace of development?

in mice and in humans and so they took mouse cells human cells themselves put them in a dish and then you look for like the rhythm of development and they found that as others had seen before, the mouse cells, which came from an animal that develops, grows, and dies in three years versus human cells, right? An organism that develops, grows, and dies in like 80-ish years. have very different developmental rates and then they ask what's different between that?

What controls the pace of development? And they found that the main driver of this, and then they did experiments where you can accelerate or decelerate the pace of development by modulating mitochondrial metabolism. And when you say mitochondrial metabolism, is it fair to go back to the analogy of the Morse code thing where the animals that develop quickly and die earlier, it's like a faster transformation of energy? Exactly.

and and that was regulated by nad i think maybe a few people who listen to this know about nad and so nad seems to be kind of a dial on you know the rate at which energy is transformed so interesting i um long ago I was getting frustrated because all the discussions in the longevity space were failing to acknowledge, I'm a developmental neurobiologist first, that...

So development is the most rapid period of aging ever. Look at a kid at one versus three. That's a lot of aging. We don't think of it as aging because they haven't peaked in terms of their vitality and their maturation yet. Look at somebody before and after.

Puberty, first of all, completely different organism of any species, right? Person, different personality. But it's probably the fastest rate of aging we ever undergo. And so I had this theory that I'd love somebody to test. Maybe your lab could do this. If you look at the rate at which people acquire secondary sex characteristics going through puberty, typically they acquire one or several all at one stage, and then it continues.

How long the acquisition of secondary sex characteristics carries on essentially is a measure of the duration of puberty because it reflects a bunch of changes in the hypothalamus. We know that. And that it cascade out to the body, hormones, and so forth. I knew kids in...

junior high school who we went away for a summer. He came back and there was a kid on my soccer team. I'm like, that's a grown man. Like he had a beard and he was, but I won't mention who this is. And he was very like muscular and lean and he would score like nine goals every time he went to the more. advanced soccer league and stuff. I saw him in my 30s.

And I was like, wow, he is, and there was no envy or upset about this, you know, or schadenfreude or anything. I really like him as a person. I was like, well, he looks like he's like 45. He had aged much more, and then I knew other people that had – they kind of matured more slowly. And sure, lifestyle factors play in here, but –

They were developing in a way as adults where you're like, wow, they're really like taking great care of themselves. But speaks to this idea, first of all, that maybe the rate which one moves through puberty is predictive of lifespan, plus or minus some lifestyle factors. So what are your thoughts on that? Is it conceivable? I think it's conceivable. And there's nice data on energy expenditure. How much energy is the body burning? to go through whatever it's going through. And again,

Nothing in biology is free. That's kind of one of the basic energetic laws of life. Everything costs energy. And in development, you see when babies are born, they're a little hypometabolic. They don't burn as much energy as like an adult per, you know. kilogram or pounds of body weight. But then within like a year, you see this massive increase in energy expenditure. And then it kind of peaks around five years of age when kids are like,

developing so quickly. My son is six years old and he's learning so much, changing all the time. So, energy expenditure is like... peaks around this time. And then by 10, 15 years old, it's, you know, around back down. And then by 21-ish, it's adult. And then it's a flat line for the rest of adulthood. Then around like 70 years old, you start to see this decline. Yeah, it's a myth that metabolism slows down.

as we age. I mean, it's true that if we don't keep our muscles and movement, et cetera, breathing, exercise, a lot of it is just breathing. Bringing oxygen to your mitochondria. Well, as a friend who's in incredible shape.

What once told me, I said, what's your workout regimen? He's in his 60s. He's in fantastic shape. He says, I make sure I'm doing something every single day where I'm breathing hard for one hour. And I said, what do you do if you're trapped on a plane? He's like, I breathe hard for an hour. Former SEAL team guy. So they're a little extreme.

But, you know, he makes a good point. But the idea is that we understand from this paper published in Science a few years ago that metabolism, basal metabolism doesn't change much as we age. We thought, oh, my metabolism slows. It's not true.

Once you hit adulthood, once you hit your 20s, your metabolism is not changing much at all, I think, as you pointed out, until one's 80s. Yeah, it depends at what level you look at metabolism. If you look at the cellular level, they're— I'm referring to the caloric— Basal caloric need. How much energy you should consume. Basal metabolic rate, like minus the running, the lifting, et cetera, that you do. Now, of course, lifting can add muscle, which then raises your basal metabolic rate.

Just this idea that, oh, my metabolism is slowing as I age, turns out to be completely false. People have used that as an opportunity to write off. They're overeating. They're over-consuming energy in most cases. Yep. We've developed a model called the energy conservation model, the brain-body energy conservation model of aging, the BEC model. And so we could dive into this. But I think there's significant changes that happen in some cells.

As cells age, they start to actually burn energy faster when cells become senescent. They burn energy faster, and then they're sending signals. I'm struggling, energetically speaking. And that's what I think inflammation is. You have some cells, not all cells, some cells in the body. They're kind of over the edge. They're becoming senescent. And then they send signals. And those signals are the same signal that we release during sickness behavior.

If your immune system is like really struggling energetically because it's trying to fight off a virus, it's going to send those same cytokines. And when those cytokines reach the brain, the brain says, oh shit, we're going to go bankrupt. You know, the energy budget is threatened here. So let's save energy. And then you become apathic, you become cold, you shrink your muscles. And those are all good energy saving, energy conservation strategies to...

a viral infection, right? The same thing seems to happen slowly as you age. If you have those cells that are sending those signals. But if you exercise and if you don't eat too much and once in a while you feel hungry, maybe intermittent fasting or...

You actually now can get rid of those signals of energetic stress and you can make the organism more efficient. I think a significant benefit to exercise is improving efficiency. And then you can... you know fight off inflammation really what this is is you're bringing the organism's energy resistance the the cells that are struggling you're kind of normalizing them and then you don't feel like you're running out of energy so i think it's a perception problem so

I'm now going to imagine that one of the reasons why we have less energy, in quotes. We feel less energy. We feel less energy. Thank you. As we age is because of inflammation. in the body calling more energy to be allocated to those cells that are in the inflamed area and they're consuming more energy. So by reducing inflammation, you have more energy to allocate to other things. Correct. Got it. And so this is very different than-

how we were talking about at the beginning when I said, you know, my advisor came up to me, why do we have less energy? I just imagined it was rundown of mitochondria. So this is what creates a kind of dynamic tension. And that's very practical for me and for everybody. For instance, I could run more to increase the number of mitochondria in my body. I can...

Sleep a little bit more to offset the inflammation from the running, but ultimately I'm playing a game. I have to budget. Am I going to exercise more to get more mitochondria? So my brain and body have more energy, but I'm also going to create some inflammation when I exercise, and that's going to eat up a bunch of energy too. So it's just like time or money or anything else. You can't do everything.

You know, my mindset has always been, and I think I'm going to stick with this, frankly, lift weights three days a week, do cardio three days a week, rest completely one day a week. Do the other things like sauna and cold as you see. But make darn sure you're getting six to eight hours of sleep each night. I've been pretty religious about that for a long time. And try to not burn energy on.

drama or mind numbing things and certainly don't use any substances that use up a lot of energy excessively i do drink a lot of caffeine but you know like prescription stimulants that i know people rely on a lot like I'll just call it out, modafinil. I've taken it once when sleep deprived. You feel as if you slept eight hours, but you're borrowing that energy from someplace. And it's not just the crash that happens later.

It's the long-term effects of this. And I think this is why people who use amphetamines and cocaine and things like that, stimulants, we often find that... sure they die of heart failure that's very common actually people who use cocaine earlier we're going to talk about this but let's just be direct about it they're borrowing energy from the future is what you're doing and so i think

I'm a big fan of people exercising more, eating better, et cetera. But at some point, you're increasing inflammation that way as well. Inflammation is a reframe that, to me, completely changed my perspective on what inflammation is. Inflammation is an energetic signal. If there are cytokines in your blood, it means somewhere in your body, and that's not true of all cytokines, but the major cytokines that we think about, like IL-6, interleukin-6, it's secreted by muscles, not during the exercise.

Like you're doing your run, right? Like I'd say you run intensely for an hour or two hours. IL-6 doesn't increase. It's when you stop exercising, boom, you get this beautiful spike of IL-6. And then you ask, what is that? So IL-6 is a cytokine, right? It's a cellular signaling system. And then IL-6 goes to your fat. And then it says, we need energy.

Like lipolysis, chop out those, you know, lipids that's stored in your fat, release that in the blood because the liver needs it to make glucose. And then the IL-6 goes to the liver as well and then tells the liver, make glucose because the muscle is depleted. And the IL-6 burst after exercise is particularly strong if you're glycogen depleted.

Right. If the muscle is out of its internal. Like after resistance training or sprinting or high intensity training. High intensity. Yes. So then the IL-6 then is a signal, right, to mobilize energy. It's the muscle's way of telling the rest of the body, I'm running low on energy. right? Please help. And then it recruits the fat, it recruits the liver, and then it sends signal to the brain. The brain has IL-6 receptors as well. And it says, you know,

Feel like crap. Like you need to recover. Lose your vitality, your vigor, at least for a little bit. And rest. And like, you know, Arnold said, you become stronger, you make your mitochondria, more mitochondria, and you become fitter not during the exercise, it's during the rest period. So, you know, getting sleep six to eight hours. Definitely. And about stimulants like caffeine and other stimulants, what they do is they prevent you from feeling energetic stress.

So if energy is not flowing properly in your body and you should be sleeping to kind of decrease that energy resistance, then those stimulants kind of make you oblivious to those signals. And now there are clinical trials, which I think are potentially dangerous, that are happening where those drugs are being developed, antibody-based drugs, to prevent the brain from feeling signals of energetic stress in the body.

That sounds like a terrible idea. Well, if you think about it simplistically, and you think the body is a molecular machine, you think, here's what's happening when people are sick to have cancer. GDF-15. This growth differentiation factor 15, which is a protein, it's a cytokine. It's secreted by cells when energy can't flow properly in mitochondria. So if the cell is burning energy faster than it can sustain.

it will start to secrete GDF-15. So people with cancer who end up developing cachexia, or their muscles melt away. they tend to have very high GDF15. And then GDF15 can go to the brain. And as far as we know, the only place, or as far as the community believes, the only place where there's a receptor for GDF15 is in the brain. But the brain doesn't make GDF15. GDF15 is made by every other organ in the body, including tumors. So what happens is that people with very high GDF15 feel terrible.

And if you actually inject GF-15 into an animal to ask, what does it do? Like, what does GF-15 mean if you have a lot of it in your blood? Well, animals actually puke. And it caused, you know, an aversive reaction. Visceral malaise is the technical term. So you feel like shit. GDF-15, which is produced by cells... struggling energetically anywhere in the body, signal to the brain and makes you feel like shit. We know now also GDF-15 is the trigger for morning sickness in pregnancy.

So the reason, you know, women, especially hyperemesis gravitarium, HG, which is like terrible women who have this. Many of them want to terminate their pregnancy. It's so horrible. Like if GDF 15 rises like 10,000 fold. There are not many hormones that can increase that much. During pregnancy, the placenta sends out GTA 15, maybe to tell the mother, like, chill out.

reallocate your energy. You're growing something that is costing a lot of energy. So we know GDF-15 does this. So now what pharmaceutical companies have tried to do is to say, okay, let's block GDF-15 signaling so people don't feel like shit. And so there's this one trial that was published in the New England Journal last year, and they show, as expected, if you block GDF-15 with a monoclonal antibody, people don't feel as terrible. And they eat a little more, and they don't lose as much weight.

Right. So it's basically if you're sick in a hospital, you have cancer, you're getting chemo, you don't want to eat. Right. And energetically, I suspect this is the right thing to do. Because you're saving 10, 15% of your energy budget, reallocating it to healing processes, your immune system, whatever the body needs to survive that challenge. Now you're kind of depriving the brain of that signal. So people actually don't lose as much weight.

So then that trial said success. If you look at the fine print and you look at the table where they report mortality, mortality was double in people who were receiving the drug. That trial was not the... powered to detect mortality as a primary outcome. It was, you know, powered to detect changes in body weight. So that didn't end up being a main finding. But if this is real...

right? You're preventing people from losing weight and they feel a little less nauseous, but there are twice as many people who died during that trial. Because the body is smart and it knows to not allocate energy to... eating under normal conditions. There's nothing normal about chemo conditions, but I think you understand what I mean. That the body's intuition to not eat is smarter than any kind of...

you know, molecular chicanery to overcome that signal and have you be hungry. And you would think, oh, they're getting more nourishment. I thought you were going to tell me that more of them lived. You're saying twice as many died. Died. And recently, there's another trial, large-scale trial for heart failure that looked at this, using this antibody to...

Because when the heart struggles, dilated cardiomyopathy or congestive heart failure, energetically, it's really demanding for the heart to be pushing against high blood pressure or to be failing, right? So there's an energetic stress in the heart at that point. GDF-15 goes through the roof.

So now people know in cardiology, GDF-15 is a really good marker of heart failure. And then the thinking, I think our way of thinking energetically about GDF-15 is a little different than what the rest of, I think, the field.

things that people see gdf-15 as a marker of inflammation and then maybe that's like immune or i think it's a marker of energetic stress the heart is calling out for help and trying to kind of calm down the rest of the system right and by signaling onto the brain Turns out many more

people developed heart failure and like adverse events under the drug. So they stopped the trial. Where you block GD15. Yes. So if you block... This is the danger of molecular thinking of everything in terms of receptors and ligands, like the things that plug...

in people might not know what ligands are things that plug into receptors and activate them i mean i love modern biology there's a lot of beautiful things but the it the systemic effects are hard are impossible to predict i guess that's why you run these trials

I do have a question as it relates to this which is a big theme of your work which is about stress. Well, I'm sure people are wondering by now, tell us about the gray hair reversal. So let's start with that. Let's just get that out of our systems. I will say, despite some theories, not that anyone cares that much, I've never dyed my...

The hair on my head, I do have some grays, but the number of them waxes and wanes with how much sleep I'm getting. It's kind of interesting, perhaps. But my beard's gray, right? And I'll tell you, I'm not... sure that all gray can be reversed by just reducing stress. But I don't dye either my hair or my beard, so I'm a natural experiment in this.

What's the deal? Can people reverse the graying of their hair by reducing their stress? Can people accelerate the graying of their hair by stressing more? Likely both are true. Yes. Okay. And I think what we discovered is that... Hair graying, at least temporarily, is reversible. And this was surprising because it goes against this notion that aging is a linear process that...

just happens over time no matter what you do. And here we should know actually a hallmark of aging, which is, you know, depigmentation, losing color in your beard and your hair. It's something that happens. to almost everyone but at different you know stages of life and so on and then on the same person and the reason we got into this was that

this felt like the perfect experiment. Like you have every hair on your body is about 100,000 hairs on your head. Every hair has the same genome. They're all genetically identical twins. Right. And they're all exposed to the same exercise regime, the same food, the same stress levels. Yet some hairs go gray when you're like late 30s and then some hairs go gray when you're like in your 80s.

What the hell is happening? I thought if we could figure this out, the basis for the heterogeneity, the hair-to-hair heterogeneity, maybe we can understand why different people age at different rates. Because it's very clear that there's no more than 10%. of how long you live that's genetically driven. Like the best studies put this at around 7%. 7% of longevity is genetically inherited maybe. And then about 90% is not. Is lifestyle factors. Lifestyle.

You know, food, exposures, whatever is non-genetic. People will take solace in those numbers. Yeah, I think those are really powerful numbers. And they surprise me because I had learned. you know, through my training, education, that the majority of how long you live is, you know, your parents. And I think this is legacy. It's like dogma.

It's not science-based. It's dogma from, you know, the Human Genome Project era. Like through the 90s, we were hoping we would find the gene for cancer, the gene for heart failure, the gene for Alzheimer's, the gene for schizophrenia. And then the human genome was sequenced, 2001. And then there was like 10, 20 years of GWAS, Genome-Wide Association Studies, trying to find...

people who have this disease and trying to find which gene do they have that other people don't have, right? Those large-scale studies. And if the Human Genome Project and the search for causal genes for common chronic diseases... had been an RCT, it would have failed its primary endpoint. I think if we're real about this, the hypothesis was wrong. It was a useful hypothesis, like many hypotheses are. It led us to learn a bunch, and the human genome...

The sequencing that was such a driver of progress in biomedical science, but it's failed to solve the big... Mysteries about why we get sick when we get sick. No genes will tell you this. Yeah, I would say the Human Genome Project, like so many things, the brain connectome, proteomes, inflamatomes. Necessary, but not sufficient. Correct. We want and need the information, but it's not sufficient to demonstrate anything except it's a hypothesis generating.

I know this because I sat on grant panels for a long time, and you look at these incredible studies, like we're going to measure the difference between this cancer cell and that cancer cell, and it's great, but... The information you get is necessary, but it's not conclusive of anything. But it is good work.

Yeah, it's good. Of course, it's good. There's a lot of really high quality science that's happening. But I think in general, academic science has kind of lost track with its core purpose. And now we have like an incentive system. There's a lot of forces at play in administrative processes that... Don't serve the primary end goal, which is – Well, it's all getting revised now. So it's – for better or worse, it's all getting revised. So I see your point. I'm warmed by the fact that –

even though my parents are still alive and are doing well, thank goodness, that only 7% of longevity is dictated by the genes. So if you have parents that lived a long time, this also means you got to keep...

Upkeep is important, but what you do is key. So with respect to... graying hair isn't the most important problem people can dye their hair right if they want to uh people can shave their head if they're losing hair like there are a bunch of ways around this monumental problem of graying hair but i think what it illustrates is really interesting so

That there's plasticity. Yeah, so could you explain the result? So when we started to think about this, we thought, what if we found hairs that have, like the same hair has two colors, right? So you have a piece.

of a segment of the hair that is dark and then a segment that is white. And then if you could find a hair that was dark, so the tip... the tip of your hair, you know, used to be inside the body. It's a bit like tree rings, right? If you cut down a tree and you look at the tree rings, you can basically go back in time and say, ooh, 20 years ago, there was a fire here, right? And then 45 years ago, there was a drought.

And the tree rings look different. And so there's information encoded in the structure, right? So we all walk around with kind of a molecular record, like a physical timeline. of our biological history. Stressed, relaxed, good relationship, bad relationship. Yeah. So if, and Harris grow it about- Writing a grant after the grant. Yeah.

That was actually part of the data for that study. I was one of the participants early on because we became interested in this. We found hair that were two colors. The tip was dark and then the root was white. And then we thought, oh, if we can figure out...

that hair transition. And then if you measure it and you know how quickly the hair grow, then you can say, okay, two and a half months ago, right? And you can look at the calendar and say about here, this hair went from being dark to being white. what happened in this person's life right so that was the idea uh and then uh back then my partner uh went to the bathroom and then she she brought back like she had very long hair and then you could see like

Clearly the same hair, two different colors. It's like, shit, aging. Hair graying is, there's plasticity here. And then we found hairs where the hair was white and it went back to being dark. This was a little confusing. And then we had one participant who brought a hair, a young Asian woman, and her hair was so beautiful. She had like really dark hair, and then their root was dark, and then there was a segment, two centimeters.

but like almost an inch of white. And then the rest of the hair was dark again. What happened in that two centimeters? Did she share? Yeah, exactly. So that became the question. So then we developed, we said, okay, we need to do this quantitatively. She didn't tell you what had happened? No, no, no. We were collecting hairs in Ziploc bags. So now people started to mail us, you know, Ziploc bags with hair.

And we got some hairs from France, hairs from Canada, from different places in the U.S., across body regions in South Asian, African-American, you know, white. It was clearly real. And then we thought we need to develop an objective, semi-quantitative method to... quantify stress because we quantify now we we bought a scanner you know old style like photo digitization system so we bought one of those high-end scanners and then we could iron out like a single hair

tape it down and then like scan at super high resolution. So then we can get like a digital readout of the hair, like tree rings. And then you could see, okay, the hair was dark and there's actually information. There's like... It looks like EEG almost, but we're looking at hair color and then it lost color. So then you can say, okay, this is the point. And then we needed something similar for psychological states, right? What happened in this person's life?

Ideally, you would get blood or saliva or something else. But we could go back in time with this. And then I sat down with this participant and said, Okay, this is now and this is a year ago. And then you can look at your calendar. What was the most stressful part of the past year? And then for her, it was very clear. And then what was the least stressful part of the last year? And then people would rate this. There's the y-axis as most stressful at the top, least stressful zero.

at the bottom and then they put points and then connect the dots right with the line so then you end up with a line graph of someone's, you know, recall of their stress levels anchored in some, you know, objective life events. So that was the methodology we use. And for her, and she had sent us the hair a few months ago, and then...

And we were doing the interview. And her profile was so beautiful. And she said, I submitted my thesis. She just graduated her PhD at Stanford, actually. And then she... You know, had a chill summer and everything was OK. Then she had some issues with her boyfriend and they broke up. And then she was like in crisis. What do I do with my life? Do I get this job or that job? She had to go to Europe for some family issues. And then.

And then she ended up moving to New York City, getting a job, reconnecting with her boyfriend, and then life was great. And her graph looked exactly like this. And that period lasted two months. And it mapped to the gray zone. It mapped. surprisingly perfectly with the graying, right? Where the hair lost color. So it was the hair, the stress peaked for two months and then came back down. She said, these were the most stressful two months of my life.

super interesting and that the paper's got a lot of press as it should be. I've received about 300 emails since that paper was published. People from sending me pictures from all over the world saying like, I found this, this two colored hair. I thought I was crazy. Google this and found your paper. When I was growing up, my dad told me that he had a cousin who.

worried so much that he went to bed one night and woke up and all his hair was on the pillow. And I didn't know until I was an adult that that story was designed to get me to stress less and that it wasn't completely true. But that's hair loss, not graying. Is there any graying of hair, beard hair or head hair, that is just simply related to age? Or can we say that any graying of hair that's age-associated...

is likely to be associated with the increased inflammation that comes with aging, a.k.a. stress, a different kind of stress, not psychological stress. Yeah, maybe it depends how we define stress. We define stress as anything that costs energy. Well, inflammation costs energy. Inflammation costs energy. And making a cytokine costs energy. And if you're a cell and you have a receptor for a cytokine, and the cytokine docks, the ligand docks, that's going to cost energy.

It occurred to me that, based on what you've told us, that when we're young, we need a lot of energy. And we don't want kids to overeat, but they need energy. And their levels of inflammation are very low. Kind of a perfect situation for development. As we get older, we generally move a bit less.

Or a lot less. Or a lot less, yes. But ideally, it's just a bit less. Or maybe we move more. And in general, people need to eat less, not more, as a rule. Okay, but there are always exceptions to that rule. But there's a lot more inflammation, so we're actually much more energetically expensive because of inflammation as we age. And I'd be willing to bet that some of the graying of hair is related to the aging.

inflammation thing. I mean, my level of stress, who knows what it is because it's been jagged line for so many years. I don't know what baseline is. I drink caffeine. Like most people, we're masking a lot of the things that are going on. I love the results showing that increased stress graze hairs and reducing stress ungraze hairs. It's a correlation. It's a correlation, but it's a really cool result.

I want to talk about restoration and recovery of energy. Maybe with the hair graying, I think what connects the hair graying with everything else we've talked about. is the analysis we did of knowing like molecularly what happened in the when this one hair goes gray and then it recovers its color.

What's happening energetically? So we took a single hair and chopped it into pieces and did proteomics. You have to because you're a molecular biologist, right? And I mean, mitochondria is our way to tap into, you know, the biology of energy. So then we thought maybe there's something there. And initially, I didn't think there were mitochondria in the hair. It turns out every hair that we walk around with is loaded with mitochondrial DNA.

And, you know, forensic, if you find a hair on a crime scene, you can figure out who is there. The DNA that gets sequenced is not the nuclear genome, it's a mitochondrial genome. Really? And because hairs have a very high concentration of mitochondrial DNA. So you guys, you can't commit a crime and expect to get away with it because if you leave one hair, Martin's lab is going to sequence it. We don't do forensics. Sure you don't.

The signature, the molecular signature that was the most robust comparing the white hair to the dark hair in the same person or comparing white to dark in different people was mitochondrial proteins. And I did not expect that. And we repeated those experiments in two different proteomics core. You know, there's...

And the protein we score hated that experiment because hair is like notoriously, it's full of keratin, those super high abundance proteins. And then they mask every other signal. But we were able to kind of get... good resolution data for other non-keratin, non-HER proteins. And three mitochondrial proteins were consistently upregulated. There was more of the mitochondrial energy transformation machinery.

in the gray hair compared to the dark hair. Love the direction of that result. I don't love that stress increases graying, but I love the direction of that result because it's yet another brick on the wall of what you're telling us that... Stress is an energy requirement. Inflammation associated with aging is an energy requirement. Being sick creates different energy requirements, and we need to obey these different energy requirements. Fascinating. So in terms of removing...

or reducing metabolic demand in order to keep our system going. First, of course, is sleep, right? You were telling me earlier before we started recording that during sleep, how much does our metabolic needs... Become reduced. Decreased. Yeah. Most people know when you sleep, your heart rate goes down and a bunch of your body temperature goes down. And that allows us to go.

to stay alive with 10-15% lower energy expenditure. They're different between different people, but 10-15% is kind of an average of how much energy you're saving by sleeping. There's a theory of... Why does every animal need to sleep? And if you sleep-deprive a mouse or a rat or an animal, they die eventually.

And we know from like severe cases of mania and, you know, bipolar disease, people can die from going without sleep for, you know, multiple days. So, and that might be one hypothesis because sleep... saves or conserves energy and and if you don't go into that state of like torpor right almost like hybrid mini hybrid hibernation uh then you somehow the organism can't sustain that and i we have some thoughts as to

why this is i was reading recently about this glymphatic clearance of waste in the brain that occurs during sleep and uh there was an interesting figure in this paper showing that every mammal puts its head down during sleep. And there's some cute pictures of pandas sleeping on their side. The giraffe apparently puts the top of its head down in order to presumably increase glymphatic clearance. But I could also imagine that... Resting one's head reduces energetic demands.

Some people can sleep standing up, you know, against a pillar or something. I've done that, falling asleep like that a bit. But in general, sleep is a time when we want to rest our body and our mind. And with the exception of rapid eye movement sleep, when the brain is very active, sort of a reboot of sorts. periodic reboot um sleep just seems like this beautiful way to allow the mitochondria to either restore or you just you don't want to

You can't out-eat sleep deprivation either. You can't eat more to get more energy. That's very clear. Yeah, that's a very important statement. Now, I'm... long been curious about things that people can do in order to either reduce their sleep need or I prefer to refer to it as increasing their vitality while waking. And it is true. There are data showing that people who meditate.

for an hour or so per day or two 20-minute sessions, seems to be the most typically used protocol, can fairly dramatically reduce their sleep need and really go from like an eight-hour need to a six-hour need. with a 40-minute investment of meditation. What are the data on how meditation reduces mitochondrial function and energy use? I want to start by saying we don't know what mitochondria do when we sleep. Like do mitochondria sleep?

You lose consciousness and the body goes into this hypometabolic restorative state. And yes, there's glymphatics and garbage clear out in the brain, which I suspect might have an energetic effect. If you have garbage in your brain, probably the brain becomes less efficient. So it needs to burn more energy to do the same thing. So maybe the reason why the brain clears out stuff and why that's...

an important part of sleep is for an energetic purpose. So we just finished an experiment where we had people come in the lab. for 24 hours, sleep into the lab. And Evan Cholson, a student in my lab, is analyzing those data. And I think for the first time, we'll be able to know, what do mitochondria do when you fall asleep?

And you go into this hypometabolic state and you're kind of conserving energy. How is energy reallocated? So we see sleep as a two-arm process. One, it slows some things down. If the heart beats, you know, 10 times less per minute, like that's a lot of energy. Every time the heart contracts, right, systole, diastole, both contraction and relaxation cost energy. And then if you do this...

10 times less per minute, that is a bunch of energy that can be reallocated, redistributed. So we suspect that there's three main buckets of energy expenses that the body needs to sustain at some... point in time. One is vital. You need to keep your heart beating, you know, your resting heart rate, the brain function, your kidney. You need to be, you know, detoxifying, clearing the blood and all of your vital organs. That's vital cost. Second is stress cost.

If your sympathetic nervous system is activated because you're worrying about the future or worrying about the past or you're stressing yourself out, this costs energy. And then your blood pressure increases, that costs energy. Heart rate increases, costs energy. You're sweating a little bit, costs energy. Your hair rises, you know, anything that you're doing will cost energy and then steal that energy, we think, from a third bucket. which is what we call growth, maintenance, and repair. GMR.

And those GMR processes happen at the level of organs, right? When you have an organ that gets bigger and stronger, for example, after weightlifting, it can happen at the level of a cell. If the cell needs to repair its membrane, needs to repair its DNA, this would be growth, maintenance, and repairing. If you make more mitochondria, mitochondrial biogenesis after a workout, that would be growth, maintenance, and repair. And because there's a...

a finite energy budget. There's an economy of energy. how much energy you have needs to be distributed between those vital costs, the stress costs, and the GMR, growth, maintenance, repair costs. So if you're stressing out all the time, we suspect this actually steals energy away from GMR.

And then you're not healing, you're not growing, you're not learning maybe. And what sleep might do is actually shut down all of those stress processes. When you sleep, heart rate variability increases, right? Parasympathetic. tone increases, sympathetic nervous system goes very quiet, and then all of the stress-related expenses then become quiet, then that energy...

piece of the energy budget can be allocated to growth, maintenance, and repair. And when you meditate, and there's this beautiful study that shows expert meditators can... go into a deep state where their energy expenditure goes down by 40%. Wow. So 10% to 15%, we said earlier, that's how much you can save energy by just sleeping.

Meditating, it seems, and some trained people can bring energy expenditure down by 40%. This is more than sleep. So they're able to shut down, right, or quiet down maybe vital processes. Like we know the heart rate can go down extremely low. Probably stress processes. We know this from measurements and meditators. And then maybe that energy can be reallocated to growth, maintenance, and repair. So if you do more of GMR.

and you're waking life because you live more mindfully and you don't stress yourself out, think about the future or the past or, you know, self-related thoughts, then maybe you can do more GMR. during meditation or during your daily life, and then you don't need as much sleep. If the purpose of sleep is to reallocate energy towards growth, maintenance, and repair. It's definitely been my experience.

i've talked before on the podcast i'm a big fan of yoga nidra or i coined a variation on it non-sleep deep rest uh you essentially consists of lying down intentionally staying awake and uh for 10 to 30 minutes and you do a progressive bodily relaxation while keeping your mind awake the reason it's useful is twofold one you emerge from it with a

ton of energy, mental and physical energy. Your vigor is restored even on less sleep. The other is that it doesn't impede your ability to sleep at night if anything it facilitates it whereas naps can often create a sleep inertia you feel sleepy afterwards then people drink caffeine and then that can cause issues or just even make it harder to fall and stay asleep at night after naps, whereas non-sleep deep rest, yoga nidra is very, very efficient this way. The other thing is...

that I've been playing with lately that I've found to be tremendously useful. I sort of joke about this. I was telling my girlfriend the other day, like, we'll just say for the hour or so before sleep, to just, like, listen to music, have the lights dim, just, like, really relax. Or maybe the 30 minutes before sleep, just really relax. And it's almost as if, I mean, you're awake. You're not asleep. But... I noticed that it dramatically reduces my sleep need.

I wake up from six hours feeling like I got eight. And I monitor my sleep. And so it's a pretty robust thing. I suspect it's the slowing of the heart rate before sleep. I suspect that's what it is. Because it's not actual sleep. It helps you get into deeper state of sleep faster? I think it's restorative in its own right. And it probably helps sleep as well because it's anti-stress. And so, you know, it's hard to tease those apart.

But I think this idea of not just lowering the lights, dimming the lights, but also reducing the heart rate as you head into, you know, getting ready for sleep, you know, brushing your teeth, getting ready for sleep, you know, and... Pre-sleep activity is being very relaxing. We hear that for the de-stress component. But I suspect that the brain is already going into a sleep-like state. Yeah, so I suspect that's accurate. And if you're...

By, you know, creating that environment and then it allows you to relax, right? What relaxing means basically is you decrease the energetic cost of sustaining your organism. and then lowering heart rate, lowering cortisol in your blood, norepinephrine, catecholamines, and the things that cost a lot of energy. We've done experiments in cells in a dish. You give cells glucocorticoids, like a...

Cortisol mimetic or norepinephrine. And then we wanted to know how much energy does it cost, right? To mount a stress response. Like those hormones are not damaging by themselves. But if you give them to cells... Those cells go into a whole choreographed, evolutionary, ingrained response that prepares them for the future.

It's called allostasis. And that costs a bunch of energy. And we found it was about 60%. So this doesn't happen in human beings. But if your energetic metabolic rate increased by 60%, Right? With glucocorticoids, you'd be in big trouble. So it might not be as much in the whole body, but we know now that just a stress hormone...

on cells, you know, in a dish, human cells, is able to increase the energetic cost of life. So it costs energy to worry about stuff. So if you can decrease the level of those hormones and decrease the level of cytokines in your blood, inflammation. That's going to save energy. And then, yes, maybe sleep is more restorative. And the sleep study we did, there are people whose sleep energy expenditure drops significantly, like 20%. Other people doesn't drop it.

you know almost at all in particular people whose mitochondria don't work very well So we've been so fortunate to work with patients, and I'm not a physician, but I'm in the clinic half day a week, and I see patients that I've followed now for about six years who have genetic mitochondrial diseases.

So they're pretty rare, but they have a mutation or a deletion in the mitochondrial DNA. Some of them is in the nucleus, nuclear genome, but it affects the mitochondrial energy transformation capacity. Those people are always tired. You know, they don't feel well. They avoid exercise at all costs because it just feels so terrible because their mitochondria have increased resistance to energy flow. So if you try to push more energy through, it's really uncomfortable. GDF-15.

through the roof the best biomarker of mitochondrial disease is actually gdf-15 which you know tells us something about the where what gdf-15 means to the organism when the mitochondria don't work properly those cells that can't flow energy properly send out GDF-15 as a signal. And if you do a sleep study on those individuals and you look at how well do they decrease their energy expenditure to go into this restorative state, the parasympathetic nervous system can't kick in.

Some of the biggest difference we see between mitochondrial disease and people who have normal healthy spectrum of mitochondria is this inability. to slow down and to go into this restorative state at night. So that positions mitochondria. In the context of restoration and, you know, our ability to heal and lifespan in those people is decreased by about three decades. As long as we're talking about sleep and...

meditation and lowering one's heart rate before sleep by whatever means. We should talk about nutrition and exercise and supplements, dare I say. And prescription drugs, including the GLPs. So I realize you're not a nutrition expert, but you think about energy. You can't out-eat a bad night's sleep.

But we all need nutrition. When you personally step back from all the noise around nutrition, what are the key takeaways for you in terms of how you think about optimizing your... mitochondrial health and energy flow yeah i think we've gotten things wrong for two main reasons one is we don't think about the individual we try to find

One size fits all solutions. Carnivore is good or keto is good or high carb is good or, you know, meat is bad or, right? There are all of these variations which people feel really strongly about.

uh and this brings us back to like the value of the human experience like you know for yourself if you try if you change your diet and it changes your life like you have vitality you haven't had in like 20 years and your symptoms inflammation right is gone and you have clarity of mind you've never had i've met several people now who've had this kind of life changing

energetic shift happen when they go on a ketogenic diet and when they instore intermittent fasting. Life-changing shit. So they know that this is real, right? And then you do an RCT. Randomized control trial. Yeah, thank you. You do a randomized clinical trial. And then what you do there is you feed everyone the same thing. Ketogenic diet or...

standard Mediterranean diet or whatever, you know, diet as usual. And then people are on this diet for X amount of time, 12 weeks. And then at the end, you compare whatever outcome you determined you decided was the right outcome.

And then you have like, let's say 50 people here, 50 people here. And then you ask, did the ketogenic diet improve mental health? Or did it reduce inflammation? Or, right, did it do that? And then often in RCTs for... dietary interventions or drugs, what you find is not really. Maybe a little bit, right? And then if the study was adequately powered and there's like an 8%, you know, shift in your primary outcome, then it becomes P less than 0.05, the P value, the statistical, you know.

Value here becomes significant. And now you say, ooh, the ketogenic diet is effective for this. Or the ketogenic diet does not work for X. This is, I think, highly misleading because when you peel the surface... of any randomized clinical trial, you find that there are people who were like amazing responders. Like there are people whose lives was changed, truly. And then there are people who didn't change anything. And then there are also people who got worse.

And then you average everyone. You squish everyone into this average. And then the RCT is a statistical test of averages. Nobody is the average. Nobody is actually the average. Literally. Literally. And then. The ketogenic diet could literally save lives and it could cure or be like a really solid... treatment for schizophrenia or bipolar or Crohn's disease or whatever it is for like 20% of the population. And we'll never find out.

just because we have a science of averages. Yeah, well, safe self-experimentation is the only solution to this. Yeah. The only solution. Yeah, and that, you know, there's a clash here between... the value of the human experience, right? You know that this thing works for you and that you live at a higher level, right? You can fulfill your potential. And then you see the science, you know, the capital S science that tells you no.

What you think works doesn't work. No, but it works for me. And then you have a white coat wearing person who says, no, no, I have the authority. I can tell you this RCT shows that it's not effective. And I think this really... It's damaging. It makes me angry. I feel uncomfortable when I talk about this because this is completely disregarding the human experience.

you know, in service of this, you know, framework that doesn't serve the individual. The RCT was invented for very good reasons, and it's very useful in some... circumstances, like do antibiotics work? Should you be doing surgery this way or that way? But when you get to interventions or treatments that are likely to have highly individualized effects.

And there are people who respond amazingly to this, to that. Then you end up disempowering people. So I think there's a clash of, I know this to be true from my experience. And then I have this. person in this position of authority, the scientist or this doctor that says, no, this doesn't work because the RCT showed that it didn't work. Like this is really, this breaks trust. And so I understand the frustration of so many people who've...

lost confidence in science and the medical establishment, I think for good reasons in many cases. Is it fair to say that then there is no best diet for mitochondria except the one that's energetically? not excessive, not calorically excessive. Yeah, so eating too much for sure damages the whole system, including mitochondria. So the first...

piece of response to your question is because we don't think about diet in an individualized way, we're missing the boat on actually finding diets that work for different people. So we're working on a platform that would empower people to... get some objective readout right of energetically how are they doing and then and then a framework also to you know we can all be

thinking scientifically about our own health and about ourselves. And once you realize you are the flow of energy that rushes through your body with different levels of resistance, then you can think about the food you put in your body is actually... fueling that flow right like you are the movement of energy and that is continuously fueled by you know what you put in there and then the

by the activity you do and the kind of things you engage with. So yes, we need a framework for this. We're working on that. So that's the individualized piece, right? There's very... At this point, I'm pretty convinced there's no one diet that is the best diet for everyone. I've seen people thrive on very different diets since we've been kind of working on related areas.

And a few years ago, I received a research prize, the Bazooki Prize in Science, which was so enabling. And Bazooki grew up as a family foundation who's their son. was diagnosed with bipolar disease and tried all sorts of treatments and drugs that, you know, didn't work very well or, you know, actually made things worse. And so they were in a diagnostic odyssey and trying to find something for years.

And then finally, they came across a psychiatrist who was using the ketogenic diet as a treatment. And so he went on a ketogenic diet. The mom said that I had my son back. like within a few weeks. Amazing. His mood, you know, got stabilized. He was able to sleep and he stopped kind of, you know, cycling between mania and major depression.

So for him, like, you know, that really worked. And so I was sensitized to that area of work and research and then dozens of other patients. And I've met, you know, so many people now who... manage their mental health disorder with ketogenic diet. And they test, you know, their blood ketones to make sure they're still in ketosis. And there's now a continuous ketone monitor, CKM.

you know, CGM, right? So you can test your ketones. I wore one for a month and learned some really interesting things about my body and about, you know, how... Were you ketogenic? I tried. Did you like it, being in keto? Ketosis. I really enjoyed the state of ketosis. And I think there's a reason why fasting is...

a common practice in every ancient tradition and every religion has like a fasting component to them. It puts the organism in this pro-healing state, right? Which is probably why you don't eat if you're sick. and why animals also stop eating when they're unwell. So it seems to foster, promote something. And then I had much more, better clarity of mind. And that's what a lot of patients report as well. Did you stay on it? No.

It's hard to maintain. It's hard to maintain. And I didn't feel the need. I missed berries. I know I don't handle sugar well. So I ditched refined sugars maybe like 20 years ago. Do you drink alcohol? I don't.

There's good research. When I saw that study, I was like, oh, my God. This might be why, you know, I feel like shit the next day after I have alcohol or my sleep is not good. And why patients with mitochondrial disease, like the majority of them are very... alcohol intolerant uh and and then you know you can make all sorts of theories about maybe it's like the detoxification enzyme and the liver like energetically dirt on edge right and then if you look at how much energy does it cost

To get rid of the alcohol, right? It's a toxin. So everything in biology costs energy. Nothing is free. A basic energetic law of life. So if you put alcohol in the body, now the body has to spend a precious... portion of its energy budget to removing alcohol. And it disrupts your sleep. The data came out recently. This was covered in the traditional press. I think you can look it up.

Folks, there's something like a 50% reduction in alcohol consumption in the United States. Now, I think it's the lowest alcohol consumption in something like 90 years. It's pretty spectacular. We did an episode about alcohol a couple of years ago. It turned out to be a very popular episode. And there was a, you know, the argument...

has been made by me, but others now as well, that zero is better than any. And the upper limit for, you know, sustained health is, before you start to run into some issues, is probably one or two drinks per week. But this idea that wine is good for us, there's been a reanalysis of that by Keith Humphries and others at Stanford. If you look at the way those studies were designed, and he's coming on the podcast, so I'm not going to detail it now.

The way those studies were designed was poor experimental design. All of it speaks to the fact that zero is better than any. Now, that's not to say people shouldn't enjoy a drink every once in a while if they want to, but they should know what they're doing. Are you willing to sacrifice 10% of your energy budget?

you know, going towards alcohol detoxification. Can you spare that at 10%? If you care about that 10% and you want your vitality or then maybe you don't drink. When I was going to a lot of scientific meetings, you know, there's a lot of... drinking that happens at scientific meetings. I would take solace in the fact that

A, I'm going to sleep relatively early. 11 o'clock isn't that early. But I didn't stay out late. And I wouldn't drink. And I'd watch other people in my field that I was competing with stay out late drinking. And some of them were more senior than I am with bigger labs. And I was like, I'm going to.

take your lunch. I'm going to take your lunch. The competitive edge. Yeah, that and I'd recommend that they watch certain Netflix series because that'll definitely take your competition out. No, I would watch people who are in the field of health and science degrade their their health in real time. And it was perplexing to me because the amount of alcohol consumption. Anyway, I'm editorializing now. It's bad for your mitochondria is what I'm getting. I think it steals.

a piece of your energy budget. So whether you want to allocate that energy, if you have extra energy to spare, you want to do that. That's a good way to think about it. In some cases, let's say, you know...

Vital processes, nothing you can do about this. And as you age, probably those increases. Stress processes, right? The mind creates most of those. Stress-related energetic costs. And then growth, maintenance, and repair. If you're... uh for some reason circumstantial or you know you have some some um we all have we from our paths that we deal with uh if if this is burning a big chunk of your energy budget right every day you

you're a little traumatized or, you know, you worry about the future, about your self-image or whatever. If this is burning, let's say 20%, 30% of your energy budget. And when you drink alcohol, that 30% goes to 5%, right? you're maybe wasting, let's say, 10% of your budget to detoxifying alcohol. But if you're relieving that stress, I suspect this is why there are people...

that really like their social drinking because it relieves kind of a stress energy wastage. Yeah, that makes sense. Yeah. No, the stress piece is huge. And when you...

You've set up this framework for us, which I really, really like about energetic flow as opposed to just energy coming into the system as a key thing to think about. And then how we allocate energy at the mitochondrial level, but at the... decision-making subjective whole whole person level um doing things that bring us a sense of meaning clearly is energy building not just energy expending although we can't take it so far that we're not getting enough sleep i mean you know there's always

The housekeeping that needs to be done of sleep and nutrition, et cetera. I am curious about exercise. You mentioned training for a marathon will double the number of mitochondria. At most, yes. But where's the sort of...

sweet spot of doing more exercise in order to increase mitochondrial density and et cetera, efficiency. But not so much that you're robbing mitochondria from other areas of your- of your biology that are critical? Yeah, good question. Like if you exercise too much and you're a young, healthy male, you can actually decrease testosterone level, right? Like endurance training can shut down your testosterone.

production, your reproductive system, basically. So that trade-offs, the kind of trade-offs we talked about with young females also applies to males and those kind of ways. Where that threshold is, I think, is also highly individualized. And overtraining syndrome is a very real thing. And even people who devote a lot of their life and energy to becoming better athletes, there's a limit.

And I used to be a competitive cyclist and I raced kind of semi-professionally in my college days. And I knew that if I worked out, if I was on the road and I used to do like intense and long distance workouts. If I was, like I logged all of my training, you know, how many hours, kilometers, all of this. If I did more, like 20, 22 hours a week on the bike, I would get...

like Achilles tendon, that was kind of my sweet spot or my sensitive, you know, weak spot or my knee. So there was a limit, right? And for me, that limit was 20, 22 hours. And maybe that's... why i never became a professional cyclist i i wanted to at some point i thought maybe uh after undergrad i'll be professional cyclist but you realize you need to spend a lot of hours on the bike to do this

And my limit was that, right? And I did some plyometrics and some other, you know, sprint building exercises. And I weighed like... 10, 15 more pounds than I do now. I was investing more resources there. Then when I started a PhD, I was more inspired to, you know, at some point it was like, okay, do I write this paper or do I go for a three-hour bike ride and then spend like three hours?

hour recovering, you know, making a great amount of food. And so the trade-offs at some point, I started to feel like I want to put my energy towards, you know, developing these ideas. So there was kind of a trade-off from athletic performance and muscle building towards more intellectual activities. And that sweet spot, I think, is unique to each person. And some people, I think, use running as a...

as like a therapy. Some people use eating, some people use running, some people use gambling, you know, whatever it is for you. So I don't know that there is kind of a number of hours, number of miles per week. For sure not. And whether you do something, you know, that inspires you or whether you do something and it's a fucking grind, like I think that makes a difference for how much energy.

you have to do it, and how much is good for you. I know you spent a lot of time in the gym, Steven Pressfield, who you chatted to, and this concept of resistance, right? I think that there's something there that you need to... Give the body a certain amount of resistance. And that's true physically, but also true mentally. Too much resistance crushes you.

Right. And then it's like too difficult and it's demoralizing and de-energizing. But not enough resistance is not inspiring. Like and then being bored, like being in prison, that might be why, you know, being in prison is so such a. It's a thing we do to people who've done really bad things because it is... It really crushes a human spirit when you have nothing to do. Having something to do is kind of exerting resistance to the human mind. So bumping your mind against something.

And that's something academics, I think, really typically enjoy having a problem, like being curious about something. Yeah, resistance through the lens of what we're talking about today is very interesting. I think it's worth underscoring it again because... we've established, you've established, let's be fair here, you've established that it's not just about

Mitochondria making ATP in energy, actually controlling energy flow. Transformation. Transforming it, a la the Morse code rate and content. And so there's this allocation piece, but then there's also this idea that in order to transform energy, it has to meet resistance. And that's where the transformation occurs. And so perhaps the...

The whole concept of getting more vital, getting better, learning, et cetera, it's about that feeling of friction. Yes. When I've done episodes about neuroplasticity, I've tried to really get into people's minds. The moment you feel agitation, that means the opportunity for plasticity is turning on. Your brain doesn't change if it's in a state like any other state. This is unfortunately why traumatic experiences are so good at rewiring the brain because your brain goes.

I'm not used to this much adrenaline and norepinephrine. Something, whatever's happening now is really important. And it actually grabs too much. And that's PTSD. It grabs random events. It's a whole thing. But for healthy learning. adaptive learning, you have to have the resistance. If you can do the thing, your brain won't change. If you can do the thing, your body won't change. And I try and explain this in the context of cognitive stuff, that agitation and frustration, like you had to...

Seek that out. You don't want to overdo it. I think if I wish they had told me that when I was in school. I know. Right. I mean, I was a pretty avid learner, but it's like you just want to tell people the moment you're frustrated. Awesome. Like your circuits are primed to change. Yeah. Yeah. Anyway, I get very impassioned.

Because it's how we get better. And I think most people feel that and they think, oh, they're doing something wrong. But actually, the errors signal that more and tell your brain, you have to change. It's just that the change takes time. And it takes time and it takes energy. Like the reason change is difficult, transitions. Any kind of, you know, moving house is one of the most stressful things, you know, that...

divorced, like getting divorced or changing relationships, any kind of transition. By definition, a transition requires change. which requires energy. And I suspect the reason why life transitions are difficult is because they cost energy. And we have a finite amount of it. So resistance...

The energy resistance principle is something that we've developed recently with Neurosha that encapsulates this. It says like, life is resistance. You cannot have life if there's no resistance. There's no transformation. You're the cadaver. Yes, exactly. Or you're like a beaming light ray in outer space. It just goes on. It just goes on, goes on, never transform. There's a potential for change, but there's no transformation. It's never going to change.

until it hits resistance. A green leaf on Earth, for example. I love it. It's such an important concept. And just to refer, I think, you think about... bodybuilding and you're working out how the body gets stronger the way the body gets stronger is by facing resistance right if your muscles get accustomed to a certain weight if you want to grow in strength or in mass you need to go

heavier right and so it's increasing resistance same thing if you send an astronaut in outer space their body gets like so weak their bones like demineralize and their muscles atrophy and, you know, their hearts weaken. And then they come back onto Earth and then they struggle. And that's because when you go out in outer space, there's no resistance.

The gravity is, you don't feel gravity because you're constantly falling in orbit. And then there's nothing resisting the structure of your body. They age very fast. Yeah, exactly. Astronauts don't fare well. Now they have ways to compensate for this.

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I'm curious what your thoughts are about the fast-emerging space of supplements and peptides ostensibly improve their mitochondrial function, health, output, et cetera. The ones that come to mind are the following, just to constrain it a bit because it's a huge space. Coenzyme Q10, a number of people, including me, take.

This isn't a plug for it. It's just I take it. I was told that it can help my mitochondria. I don't take methylene blue. I'll mention why in a moment. There are some peptides like SS31. becoming very popular now. Cocktails of NADSS31, things like this. People are, oh yeah, people are injecting this stuff like crazy. Oh yeah.

SS-31? I guarantee within a radius of one mile. There are a lot of SS-31 injected. We're in Los Angeles. So, oh yeah, SS-31 in cocktail with NAD. It's very common. There are a couple others. SLU, SLU, there's another one. All of this is MOTC. A lot of people are injecting these peptides in effort to improve their mitochondrial function. Would love your thoughts on this. Don't worry.

protected no matter what direction you answer. Yeah, the term mitochondrial function, mitochondrial dysfunction, you know, I think are misnomers because mitochondria have many functions. And so I think that the nomenclature, that's more of maybe a researcher kind of niche kind of thing. But I think it's misleading to talk of mitochondrial dysfunction because mitochondria transform energy and make ATP. They make hormones and they make signals.

To your point about supplements, I was a student when SS31 was discovered. And I remember the person who discovered, Hazel Seto, who discovered SS31, she was presenting at meetings. And so I've seen the, now it was commercialized, you know, stealth peptide, and then it went on the... publicly traded. So it's not lived up to its expectation. It was supposed to be a treatment for mitochondrial disease, and mostly the trials have been negative.

You know, those things, we're trying to tweak the system. I think what we're trying to do with supplements is to optimize, tweak the circuitry, you know. the metabolic circuitry that we have for flowing electrons to oxygen. In an ideal world, electrons flow from food to oxygen, like two poles of a battery, like a simple circuit, with... Like just the right amount of resistance, right? Too much resistance.

and then it feels terrible. It feels like if you hold your breath and you feel like you're going to die, that's too much resistance. Not enough resistance feels like, you know, you're unhinged and probably we think that's what mania is.

Right? Where you feel like there's so much energy that you can't contain it. And then you can't sleep. And then you can't, you know, your life kind of falls apart. ADHD is another good example. That might be. So maybe those kind of conditions, disorders of the mind, we think are disorders. of energy resistance. We don't have direct evidence for most of it, but I think that's a fairly well-supported idea. And supplements in cases when your circuitry is impaired.

Like if you're deficient in coenzyme Q10, if you take it, you're going to feel it. And if you're deficient in something like vitamin B12, there are many parts of mitochondria that require B vitamins. to to flow electrons towards oxygen so vitamin b deficiency different vitamin b's including nad can really be terrible and people have chronic fatigue-like syndromes from vitamin B12 deficiency, for example. So in cases of where there's a deficiency or you think there might be a deficiency...

Maybe supplements can help, you know, palliate those. My sense is... You know, we've evolved over very long periods of time and we're really well optimized. And the body and the mind are as two expressions of this energy flow kind of can work harmoniously together if we bring awareness to it. if we keep energy flowing through exercise, through not eating too much and being hungry once in a while, I think there's ways to optimize the system. And there's a lot of people who live long.

healthy, fulfilling lives. And they get sick once in a while, but they recover without supplements and without medical intervention. So I think there's a path. uh to get there and so i think there's a place for supplements but i've never taken a supplement and um And you have plenty of energy. I cultivate my energy in different ways. And I feel like it's a better investment of my energy and my research group. We haven't studied drugs or...

We've been solicited to help pharmaceutical companies or other supplement type to test the effects of supplements on mitochondria. If we go in that route, then I think it's one approach that...

you know, might lead useful results at some point. But I feel like my energy, my contribution as a scientist is better position and understanding the energetic basis of... mind, subjective experiences, body and developing a more holistic system for for what we are, you know, energetically and what we can do to support that.

Well, you're doing awesome work, so stay on the track you're on. I just wanted your thoughts there. And I should just say, for sake of being responsible, folks, don't inject... peptides that are for quote unquote research purposes only people are getting them on the gray market i mentioned methylene blue so i should just close the hatch on that one that i've avoided it for two reasons one i saw the images of blue brains from people who had recently taken it doesn't mean they're

brain stayed blue because they had taken it recently but there are some data that point to the fact that methylene blue can intercalate into dna and possibly cause some mutations there that worries me And there are some data as well, and Chris Masterjohn talked about this recently, that if people are mitochondrial... damage deficient dealing with carbon monoxide poisoning other metabolic issues that perhaps methylene blue because it can reroute some of the uh the

pathways for these electrons can be helpful but if people are generally healthy that it can cause more problems than it solves and that was enough for me to just say i'm going to just Stay away from the stuff. Also, I don't want to have a blue tongue like a monitor lizard. Anyway, that's not a serious thing. But it just seems a little shaky for me, and I do worry about people just taking it. And I'm—

Very happy that your laboratory is focusing on the molecular aspects, but also, as you said, the experiential aspects, meditation, meaning, purpose. And this notion of flow is something that I want to just ask you about. When you see things like Tai Chi, if you're in New York City, if you see people early in the morning, if you get up, you see them doing Tai Chi. Or years ago, I saw an interview with Iggy Pop.

musician from like the seventies. And he's like in tremendously good shape now and has always been. And they asked him like, what's your secret? They always ask these kind of like, what do you eat kind of things? And he was like, it's all in the qigong breathing and it was i chuckled because tai chi qigong breathing i personally believe

that whether or not it's running, tai chi, qigong breathing, or lifting weights, the activity itself has certain benefits related to respiration, blood flow, muscle stress, et cetera, and recovery, but that...

The additional layer of benefit comes from the understanding over time, yoga as well, the understanding over time of how to direct energy in your body and mind, to be able to force yourself to get through some hard repetitions, but then to rest completely in the rest period, to dynamically move from one position to another, not just as a physical movement, but as an exercise.

exercise in being able to anticipate, okay, here comes the painful part. I'm going to not brace myself too much. I'm going to try and quote unquote flow through it, but I'm also going to...

put some restraint and pull back. And so it's, I do think that for every physical and mental activity, there's the learning and then there's the... meta learning that comes from just having done it over and over so you you have this expectation and understanding you're learning how to allocate energy and i just like your thoughts about this so i don't think it's qigong per se

Tai Chi per se, yoga, Pilates per se, lifting weights per se. I think those have each different benefits. But what are your thoughts about learning to be a better, oh gosh, this sounds super woo, but what the heck? Energy channeler. Two scientists talking about energy channeling. Well, this is not Wu. I mean, the mitochondria flow energy, you can say they're a channel for energy flow from biochemistry to electricity to ATP.

to metabolites to reactive oxygen species. All of these are different forms or modalities of energy. Is there like a molecular reality to Qigong or to Qi or to, you know, Prana or, right? Like maybe, and maybe. if we look at all of these practices right and and we ask what's the point of consilience like what's true

maybe they all have like a little piece of the truth. Molecular biology and molecular sciences also has a piece of the truth, but it's not the whole truth. And my sense is what is true that kind of is a bigger container to... contain both our molecular physical existence and our experiential.

existence, right? The emotions, the states of consciousness, states of mind that we know are real, crazy states of consciousness that we can experience with psychedelics, for example. What can... and uh encapsulate right all of this what's the bigger truth and i think that bigger truth is that we are energy And we flow through this channel, this body, right? We have mouth, we have nose, lungs, heart, all of this you can understand.

Or anatomy. Human anatomy, you can understand as an energy delivery, an energy flow system, like a flow cell, right? Like a microchip. And then there are gates that close and open, and then you can process information. Instead of electricity flowing through, we flow food. And then oxygen is at the other end pulling on electrons. So maybe all those practices.

have something to do with the movement of energy, which ultimately is electrons flowing through your metabolism, through your mitochondria. But then there's an experiential dimension to that, which is just as real. We don't have scientific tools to measure this. We can't image this with an MRI, maybe not yet. But I suspect there's a truth there. And maybe one piece of... of that truth and that's you know the way you describe tai chi and the way you know we do exercise like you

You exercise, you push hard, and then you need to rest hard. If you don't rest hard, you're going to injure yourself and you're not going to get as strong. You're not going to grow or evolve. Mentally, we need resistance. And there's like, so think about energy resistance brings us to think, you know, there's a philosophy of education that could be built around this. You need to, you know, the art of education is finding the right amount of resistance to expose a child to.

If the problem is too hard or you're too severe, you're going to crush them. You kill their spirit. But if you don't apply any resistance, there's no rules, then the energy is like this, and then they'll never learn. There needs to be just a sweet spot. right? That's what great masters, great mentors are able to do. I think I've started to see my role as a mentor for people in the lab, you know, like this a little bit. I see them as energetic.

processes. They're transforming energy. They need the right amount of resistance and not too much. And it brings me more compassion maybe for them as energetic movements. And then I realize I'm more sensitive to the effect I have on them. But all of this movement and the Tai Chi, the exercise, you know, lifting and resting is analogous to what the heart does. The way that the heart works is by contracting systole, right?

And then by relaxing. And then contracting and relaxing. Same thing for like the way neurons work. Boom, action potential, refractory phase. You need to add that period of silence, right? Boom, action potential and refractory. Same thing with sleep-wake cycles.

You need to get awake. Your body temperature rises. Cortisol spikes up. You're aware of the world. You're exposed to stressors. If there's not enough stressors slash challenges slash meaningful things in your life, you get bored and you want to die. So you need that. but then you need to kind of let go and sleep, right? So sleep, wake cycle, same thing. And maybe all of this has evolved from, you know, our existence on this planet. Like the sun rises.

Things get warm, right? And there's energy flowing around. And then the sun sets. It's the same movement as sunrise, sunset, you know, day and night is contraction, you know, resting, yoga. The whole, you know, practice of yoga is based around this. Like you strain your muscles. a great port, crazy positions, you know, immense resistance on your muscles. And then for what? For shavasana. And the whole point of yoga is shavasana.

So you're ready to body by, you know, bringing so much resistance into it so that you can finally relax. And then the art of training maybe is not about the doing, right? But it's about the being. And maybe that's a broader kind of philosophy of life, but the art of being, which because if we do too much doing.

I think, you know, many professionals know this. If you're always in a doing, doing, doing, and you're never kind of sitting back and resting and just being. And being really means just flowing to use, you know, verbs. Being is just. having your energy flow and it's doing its thing and it's healing. It's healing the body and consolidating memories and everything, all the beautiful things that happen.

you know, during sleep. As opposed to transforming it into something in the outside world, like a paper or investing. And it's the balance. Clearly, what I'm hearing, and I don't want to speak for you, but what I'm hearing is that...

So much of health, mental health and physical health and life really is about states of mind and body and... mastering the transitions into and through and out of those states, but in a controlled way, learning to direct those so that we're not at the whim of, I mean, this is the challenge that we get pulled into. the drama or the numbing out of some online activity or the energy of something going on over there that...

really pulls us. And so I think we have to have that self-awareness. But I love the idea that resistance itself is the thing to seek. Not as a permanent state, but as a temporary state that you can then move through. And I think if—clearly people learned a ton today, but— If nothing else, they now understand the biophysical principle that it's through that resistance that you direct and create.

energy for something else transform you transform yes exactly thank you good managers know this like if you want to have fulfilled employees, right, and a team that really derives joy and purpose. Like, people need to grow and learn. And the way that happens is by creating the right amount of resistance. And Steven Pressfield said this the first time I heard of him. He was on the Joe Rogan podcast talking about his book.

resistance and he talks about it in slightly different ways but I think his resistance philosophy boils down to energy and he talked about how when you feel afraid of something right like as an artist i think he speaks you know as an artist and for artists like you you you you feel into like this problem or this challenge or you know this new project you're like oh like i don't know like this is scary well

I think his advice was, when you feel fear, this is the signal that there's something there for you, right? That this can help you grow. I resonate with this and, you know, I make a lot of, you know, my decisions. I can think rationally and think logically about steps in a biochemical pathway and about like logically, like in five years and 10 years, like doing strategic planning.

I have an increasing sense that when you make decisions with your heart, and basically this is by listening to your energetic state, you feel, you see something, you see someone, you're like, ooh. i i like this or like this is a little scary right um i started to ask my wife you know and she's really good at this how do you feel i think i used to ask my partner uh what are you thinking

And if you ask someone, what are you thinking? Like right away, you go into this like cognitive level, which is really devoid of like the beautiful movement of energy. If you ask someone, how are you feeling? And then if that person, if you can. You create the space for the person to really answer from that place. Then you actually get to tune in to their energetic state. And then you can be, I think, much better partner if you see a relationship as an energetic...

exchange, right? And then I can be in a better state if I know that, ooh, she's not feeling great. And then I think we've... I think the more you cultivate this kind of energetic awareness, I agree. Awareness, personal awareness, and I would say energetic awareness.

Feeling into your mitochondria, maybe that's what it boils down to. I think it's our greatest superpower as human beings. And that's not a new concept. It's, I think, the foundation for a lot of spiritual traditions, like cultivating awareness.

of self and then you realize at some point there's no self i'm this like movement of energy and then you movement of energy and then we're all kind of arising emerging from you know an underlying current of consciousness and you know their ideas about this uh i'm not sure how it all fully gels together, but awareness also as a scientist.

If you move through science without self-awareness, then your biases end up ruling the kind of projects you take on, end up ruling the kind of grants you apply to, and end up ruling the kind of science you produce and you generate. and so without self-awareness i think we're not always doing you're fulfilling our potential and uh fulfilling our collective potential right as as humanity like we can if we can be the best person that we can be

then we can help other beings being their best self. We can be present. And when you're present to someone, it's basically saying, I see you, energetic process, and I'm opening to you. You know, how are you feeling? You know, that's why I think those kind of conversations and connecting deeply with another human being is so rewarding. And that's...

That's true, I think, across the board. We're social creatures. And what this means is we love connecting with other people. And I suspect that's because it helps us flow. It helps us, you know, our energy flow. And then we love projects that are stimulating.

you know inspiring and what those words mean stimulating inspiring they're all like energetic terms so the things that helps us flow being like cognitive or spiritual or, you know, intellectual, you know, social, all of those I think probably boil down to is. Is this thing helping energy flow through my mitochondria more easily? Or is it bringing me resistance? Or is this thing bringing me resistance that I feel I have the capacity, the inner...

you know, potential to push through. And then when I let go, then I become stronger, right? And I grow as a person and I learned. I love it. It's a mitochondrial... or energy flow centric view of everything. And I think it is. the basis of life. I know you're working on a book now. It sounds like there's also another book to follow that one, The Mitochondrial Marriage, at some point. I'm only half kidding. What you described is really beautiful.

And it captures so much of what people are seeking. And I think what people understand intuitively about the things that make them feel good versus the things that make them feel bad. And we have to. pin above that that resistance is critical to growth so it's not just about things that don't take effort versus things that take effort. It's not as simple as that. It's not infinitely complicated, but it's not as simple as that. Speaking of solutions, before I...

Came in here to talk with you. I solicited the internet for some questions. We sometimes do a, not rapid fire, but brief answer Q&A. So if I may, I'm going to go fetch my phone. and gather a couple of questions to ask for some short answers. First question is, why is it that over-consuming calories causes disruption to the mitochondrial pathways?

Yeah, I think it's because it increases energy resistance. It's like a simple electrical circuit, maybe a computer, and then you're cranking up the voltage, right? So you're like pushing when you eat too much, you're putting too much. food, too much energy into the system and then the system gets overwhelmed.

And then that increases blood glucose or blood lipids. And so the effect this has, we understand it, it pushes electrons onto your poor mitochondria. Mitochondria evolved to be super sensitive. And then when there's not enough energy, they change their behavior. too much energy, they change their behaviors. There's chronically too much energy pushing on them. If you do the, we have a little equation that helps us think energetically about this called the energy resistance principle, ERP.

And this says, if you raise the concentration of glucose, you raise the energy potential, like the voltage equivalent. And then that increases energy resistance. If you're not flowing that energy... If you're not moving, you know, being active, stimulated by something, you just put too much food in the system, it increases the resistance.

to energy flow and then you start to have more dissipative losses like too much reactive oxygen species and too much you know the damage molecular damage can happen That's probably why overeating and why diabetes and why, you know, metabolic diseases increases the rate of aging and increases the rate of all sorts of different diseases. I think it all converges on energy resistance.

Someone asked, has there been any progress made on tissue or organ-specific mitochondrial optimization? And I'll add to that, and or measurement. Mm-hmm. So the measurement piece, we're working on this. Anna Monzo in our group, who's moving to Germany now, is developing a mitotyping platform.

And if you want to explore kind of the, if you're a scientist or not, and you want to explore the molecular differences between mitochondria and different organs of the body, you can go to mitotypeexplorer.org. and then explore the different mitochondria and different organs. Tissue, organ-specific mitochondrial optimization, I think mostly is going to be driven by... the the organ or tissue specific use and and you know flow of energy and that tissue like we were talking about earlier if you

train on something, you train, you know, playing the violin, you're going to, parts of your brain are going to be, you know, more activated. Specific circuits are going to be activated together. They're going to, you know, wire. together and and then you know make more mitochondria most likely and and you know probably become more efficient as well so there's rewiring at that level um

So I think mitochondria follow or are there to serve the flow of energy. So if you flow more energy in your legs, you're going to make more mitochondria to kind of increase the number of flow channels. Mitochondria has little channels to flow energy. towards oxygen so yeah i don't know that we have ways yet maybe with uh you know light therapy uh photobiomodulation or maybe electromagnetic field at some point

We need to be developing as healing science unfolds and we understand ourselves energetically. I think we need energy-based or energy-informed approaches to help. Organisms heal and probably those are going to target mitochondria. Yeah, using light or other tools to direct healing of specific internal organs. That's going to require something, a device of some sort.

as opposed to using one area of the body or one component of the brain is what I'm hearing. Yeah, most likely. Although there's some like crazy things that monks can do apparently, like increasing the blood flow in one hand, but not the other. There's even data showing that... Advanced meditators can increase blood flow in like one part of the brain. And so there might be unsuspected ways of tapping into...

using the mind basically to direct energy in different ways. I've started to see the mind as a master regulator controller of energy. Like the mind can literally depolarize your muscles, right? And then... cause you to run, right? It starts up here with the inspiration or the motivation to contract your muscles or to run or to do any behavior. This is like the mind controlling the energy flow in your muscles and then making more mitochondria.

you as a result. What are the best or most sensitive tests for mitochondrial health, if any exist? And I will say a number of questions, and there were many, many questions centered around this idea.

of how can I measure mitochondrial health as a patient or with my physician? Are there any companies that make good mitochondrial health tests? There are diagnostic tests that clinics offer somewhere, and those are good to diagnose mitochondrial diseases. There's a few companies that have popped up because this is the future. Thinking ourselves...

Thinking about ourselves energetically, realizing we are energy. If that's true, which I think it is, then what do you do about this? And I suspect we're working on developing an institute that will... really bring together the science of energy, mitochondrial biology and psychobiology with the human experience. That really is what moves us into action and determines whether, you know, our life is worth living. those things haven't been brought together.

And we haven't also explored scientifically the healing process. So we're developing an institute that will work, do the research to develop those technologies, and then we'll do the work as well to bring those into... into technologies that can reach people and, you know, people can have in their homes and maybe as a wearable or, right, as a kit that you get at home to really help you tune into your energy and know what works for you.

which diet, which supplement or which, you know, there might be, you know, it might be that this person in your life when you're with them. energetically, it really does well for you. And maybe that means it's a good person for you. And there might be other people that really suck your energy. So we're working on initiatives and new methods to...

tune into mitochondrial health. I don't know now of things that I would use to tap into the health of our mitochondria. I can attest to both the pro-mitochondrial health and anti-mitochondrial health of certain relationships. What are some... small daily tweaks that can help increase, and people said energy, but let's just use that as a proxy for energy flow. Like if you could give just one...

Two or three recommendations. There are a lot of busy people in this question list. They're saying, I've got kids. I've got a busy job. One, two or three things that are straightforward outside the typical.

you know exercise get your sleep etc what are some tweaks dare i say hacks i think trying not to eat in the morning like skipping breakfast seems like it does a lot of well for a lot of people and i've heard for a long time breakfast is the most important you know meal of the day that my dad used to say that he still believes that and i think it's hurting his health in his like now in the 60s um so i think

Like trying to be hungry once in a while is probably a good thing. And then when you feel that hunger and then you're like reflexively reaching for food, like... I think you're probably doing something good for your mitochondria. Your mitochondria, when you're hungry or when a cell, you know what we know, the science is...

If a cell is hungry in the dish, the mitochondria start to fuse and there's more kind of the social connection between your mitochondria. So maybe it happens inside the body and then you get rid of the bad mitochondria. You make more new ones that work better, more and more efficient.

So being hungry once in a while is probably a good thing. And then being out of breath. You mentioned one of your friend, I think, who says, like, I just need to be out of breath for an hour. Finding ways to be out of breath, that can be like... a run can be being at a gym you know whatever makes you breathe harder you breathe harder because your mitochondria are calling for oxygen

It's that simple. So if you feel like you need to breathe harder, it means your mitochondria are flowing more energy and it's probably good for you. Great. I need to say something about meditation. I think somehow meditation does something to our energy that is valuable. And just yesterday, there was a piece published in Nature Reviews Cardiology.

about transcendental meditation. I think that shows that the world is changing. You know, a clinical medical journal like Nature Reviews Cardiology is saying maybe there's something about like calming down the body. right and not only is this like calming down the mind sure like maybe it improves well-being this could actually be a treatment to help the heart recover right and to help treat a very serious

life-threatening disease, cardiovascular disease. So that's, I suspect there's something about meditation. I have a... 10 minutes every morning, I sit down. I'm religious about this. I wake up. First thing I do is sit down for 10 minutes with Sam Harris's Waking Up app. And it just helps me connect with my energy. And then I think... For the rest of the day, I'm a little more in tune and I probably can make better decisions and I'm more grounded mentally, but probably also physically. Awesome.

There's a lot of discussion about peptides. MOTC, humanin, SS31, also called elamipretide. I love that.

GHKU copper and various BPC-157-TB500 analogs. I told you, this stuff's getting popular. People are curious. Let me ask you this. I'll jump in on their question. I guess we talked about some of this earlier. Would you inject any of these things? I wouldn't. Would you let your sibling, mom or dad, inject these things? No. There were many questions centered around the fact that...

fertility doctors, OBGYNs, are recommending various things to improve mitochondrial health for sake of fertility and egg quality. This makes sense because the mitochondrial genes are involved in this. spindle and the formation of the embryo, et cetera. And the questions were specifically about the recommendations of ubiquinol and CoQ10, urolithin A.

These are very prominent in the health space, especially in the fertility health space right now. Is there any real evidence that these compounds can improve mitochondrial health and therefore egg quality? There's some good data on urolitin A. that improves quality in cultured cells and then in animals. So it's possible. And I think I saw recently some very compelling data on sperm mitochondrial DNA.

content, mitochondrial DNA content like persperm linked to infertility. So I suspect that this massive crash, which is really worrying infertility. We're well below replacement right now. We're having very few babies as a society. It could be that part of the issue behind this is mitochondria aren't... you know, as optimal as they should be and our energy is not flowing as freely as it should be. So I don't know about whether those treatments could...

solve the issue. My sense is the issue behind infertility doesn't arise from some molecular deficiency in our mitochondria. It arises from some higher level process that ends up messing up our energy. Last question. Feel free to pass on this one. There were a number of people who asked whether there is any evidence, animal studies in vitro or even in humans, that electromagnetic fields can disrupt mitochondrial.

flow uh this is i realized somewhat of a barbed wire topic because it immediately gets us to the place where people think oh they're you know worried about you know 5g and bluetooth and things like that but I don't know. I did an episode on fertility where I reviewed a meta-analysis of data showing that indeed, sperm motility can be impacted. But what are the data on EMFs?

or other electrical signals or other energy fields that could potentially impact brain sperm eggs if there is you know something in Most cells that could respond to electromagnetic fields, I think it would be mitochondria. If you reason about this from first principles, in the mitochondria, there's a bunch of iron, you know, iron-sulfur clusters, which... Some of them at least are paramagnetic, meaning they interact with magnetic fields.

So I think in terms of biological plausibility, I think there's basis to believe that mitochondria could be sensitive and respond and be functionally impacted by some... for, you know, magnetic fields. So that's for biological plausibility. Data, I know some data where people have measured mitochondrial respiration, right, which is...

flowing electrons to oxygen, and you see oxygen disappearing. So you can measure this very well in the lab. And then you can measure this in the absence of any magnetic field, and then with a bit of a field, a stronger field, a stronger field, stronger field. And it seems like there's an effect. on this one function of mitochondria, which is respiration. So there seems to be data that says...

This could happen. What we're talking about in terms of magnetic field there is not 5G, and it's not, you know, some, like, Wi-Fi, widely used magnetic fields or... uh electromagnetic radiation they're pretty specific and you know the earth's magnetic field which is in like very low level, seems to perhaps have an effect also on mitochondria. And there are biophysicists like my wife, Neurocia Murgen, who has done experiments with patterned magnetic fields.

which is different than just you apply a static magnetic field like with the magnet right or a field that doesn't change over time it's like a sine wave there's no information there but you can pattern a magnetic field to have information to have content like morse code you know back to the morse code analogy so you can deliver information through that and it seems uh we have preliminary data that shows the mitochondria might be changing in response to

Basically, you're beaming energy at a certain pattern instead of with molecules like glucose and pyruvate and lipids and stuff or light. Now you're beaming energy in another modality as electromagnetic waves. And there are proteins, clearly, and iron-sulfur clusters that can be sensitive to that. So I think there's some biological plausibility. There's evidence that this might happen and affect mitochondrial respiration. And...

And there's, I think, another layer of sophistication that tells us this potentially could be harnessed eventually to help kind of rewrite some energetic states in the body. Maybe we can use those at some point to promote the healing process. Love it. We'll see. We will see. Dr. Martin Picard, thank you so much. You gave us a master class in mitochondrial function. You clarified a lot of what is...

Clearly confusion for people out there, including many biologists, mind you, about how mitochondria will work and the spectacular things that they do. And the way you frame... This whole notion of energy flow, and I guess we should credit your wife here for energy is the potential for change. Right. And the behaviors.

The mindsets, the small moments where you can give yourself relief, like an exhale and just take the tension off the body, those are surely creating it energetic savings that you can allocate to other things. And to just... Think about life as a game of sorts of controlling your energy and it gets us to sleep and all the things that we love talking about on this podcast and the way you framed it is.

truly novel and is just spectacular. Also, you're reversing graying of hair. You're giving people agency over that. And I just want to reemphasize that how... incredible it is that you're approaching things at this very high level of subjective experience, this very real level that people live in all the time.

And yet you're able to bridge across all these levels of analysis down to the subcellular and biophysical mechanisms. It's really spectacular. You're truly an N of one, as we say. And I'm very excited for what you're putting together in terms of...

this scientific institute to solve healing. Your book, we'll talk again later at some point about your book. And I should probably also sit down and have a conversation with your wife because she's got some spectacular results in this realm too. She does. Just thank you, thank you, thank you for the education and the actionable items that you're providing. Thanks for coming out all this way. I'm very grateful to you. Thank you. Thank you, Andrew.

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