Huberman Lab - Using Science to Optimize Sleep, Learning & Metabolism
Episode Date: January 18, 2021“Office Hours” — In this episode, I answer your most commonly asked questions about science-supported tools for accessing more alertness, better learning, and quality sleep. I also cover when to... exercise, time meals, and how to systematically vary your temperature to achieve specific effects on your nervous system. For the full show notes, visit hubermanlab.com. Thank you to our sponsors AG1 (Athletic Greens): https://athleticgreens.com/huberman LMNT: https://drinklmnt.com/huberman Supplements from Momentous https://www.livemomentous.com/huberman Timestamps (00:00:00) Introduction (00:00:31) Sponsors: AG1, LMNT (00:05:50) Moonlight & Fire (09:25:00) Red Light: Good & Bad (00:15:45) Why Blue-Blockers Are Unscientific (00:19:20) Eyeglasses, Contact Lenses & Windows (00:22:05) Adding Up Your Lights (00:24:30) “Netflix Inoculation” With Light (00:25:25) How The Planet Controls Your Energy (00:27:00) A Season For Breeding (?) (00:31:15) Melatonin / Serotonin (00:33:50) Epinephrine vs Adrenaline: Same? Different? (00:35:00) Exercise & Your Sleep (00:40:30) Neuroplasticity & Food/Chemicals/NSDR (00:44:10) Using Sound & Smell To Learn Faster (00:46:45) Dream Meaning & Remembering (00:48:15) Waking Up Paralyzed (00:49:40) Nap/Focus Ratios For Accelerated Learning (00:52:45) Hypnotizing Yourself (00:54:05) Smart Drugs (01:01:10) Magnesium: Yay, Nay, or Meh? (01:02:10) How Apigenin Works (01:04:30) Serotonin: Slippery Slope (01:05:35) The Frog Experiment (01:08:35) Temperature (01:10:30) Morning Chills (01:28:00) Eating For Heating (01:30:30) Vagal Pathways For Gut-Brain Dialogue (01:31:50) Sex Differences (01:33:50) Self Experimentation As always, thank you for your interest in science! Title Card Photo Credit: Mike Blabac Disclaimer
Transcript
Discussion (0)
Welcome to the Uberman Lab podcast where we discuss science and science-based tools for everyday life.
I'm Andrew Uberman and I'm a professor of neurobiology and ophthalmology at Stanford School of Medicine.
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.
Along those lines, I want to thank the sponsors of today's podcast.
Our first sponsor is Athletic Greens.
Athletic Greens is an all-in-one vitamin mineral probiotic drink.
I've been taking Athletic Greens since 2012, so I'm delighted that they're sponsoring
the podcast.
The reason I started taking Athletic Greens and the reason I still take athletic greens once or twice a day
is that it helps me cover all of my basic nutritional needs.
It makes up for any deficiencies that I might have.
In addition, it has probiotics, which are vital
for microbiome health.
I've done a couple of episodes now on the so-called gut microbiome
and the ways in which the microbiome interacts
with your immune system, with your
brain to regulate mood, and essentially with every biological system relevant to health
throughout your brain and body.
With athletic greens, I get the vitamins I need, the minerals I need, and the probiotics
to support my microbiome.
If you'd like to try athletic greens, you can go to atlettagreens.com slash Huberman and
claim a special offer.
They'll give you five free travel packs plus a year supply of vitamin D3 K2.
There are a ton of data now showing that vitamin D3
is essential for various aspects of our brain and body health,
even if we're getting a lot of sunshine.
Many of us are still deficient in vitamin D3.
And K2 is also important because it regulates
things like cardiovascular function, calcium in the body,
and so on.
Again, go to at lettagreens.com slashberman to claim the special offer of the 5 free travel
packs and the year supply of vitamin D3 K2.
Today's episode is also brought to us by Element.
Element is an electrolyte drink that has everything you need and nothing you don't.
That means the exact ratios of electrolytes are an element and those are sodium, magnesium,
and potassium, but it has no sugar.
I've talked many times before on this podcast about the key role of hydration and electrolytes
for nerve cell function, neuron function, as well as the function of all the cells and all
the tissues and organ systems of the body.
If we have sodium, magnesium, and potassium present in the proper ratios, all of those cells
function properly and all our bodily systems can be optimized.
If the electrolytes are not present and if hydration is low, we simply can't think as
well as we would otherwise.
Our mood is off, hormone systems go off, our ability to get into physical action to engage
in endurance and strength and all sorts of other things is diminished.
So with element, you can make sure that you're staying on top of your hydration
and that you're getting the proper ratios of electrolytes.
If you'd like to try element, you can go to drink element
that's LMNT.com slash Huberman,
and you'll get a free element sample pack
with your purchase.
They're all delicious.
So again, if you wanna try element,
you can go to elementlmnt.com slash Huberman.
Okay, let's get started.
Today is episode three of the podcast
and it is office hours.
Office hours, as many of you know,
it's where students come to the office of the professor,
sit down and ask questions,
requesting clarification about things that we're confusing
or to simply go down the route of exploring
a topic with more depth and detail.
I asked for your questions to be listed in the comment section of the previous two episodes of the podcast on YouTube,
as well as on Instagram. And I first of all, I just want to thank you for the many questions
they are excellent. We read them all. We distilled from that large batch of questions to two types
of questions,
questions that were asked very often,
and were liked very often with the little thumbs up,
like tab, as well as questions that we thought
could really expand on the topics that we've covered
previously.
And today we're gonna cover both of those.
If we did not get your question,
please don't despair.
We will keep track of those and we have several
more episodes devoted to this topic of sleep and wakefulness and learning during the month
of January, maybe even, you know, leaking over a little bit into the month of February.
So we have time. That's one of the unique formats of this podcast is that we have time for
dialogue. We have time for your questions and we have time to really go deep into these
topics.
It's official, Costello's sleeping in the background. So if you hear snoring, Costello is going to be keeping time
with his deep and melodic snoring. There different categories. Light, exercise, supplementation,
temperature, learning, plasticity,
and mood and sort of mood-related disorders.
There were a lot of questions about those.
Before we begin any of this, I want to point out something that I always say,
it sounds like boilerplate, but it's important not just to protect me,
but to protect you,
which is that I am not a physician,
I'm not a medical doctor,
I don't prescribe anything,
including behavioral protocols.
I'm a professor, so I profess a lot of things
based on quality peer reviewed studies.
You should take that information,
you should filter it through whatever it is
that you currently happen to be dealing with,
whether or not that's health or illness,
you should consult with a licensed healthcare professional
before you add or remove anything
from your daily life protocol.
I'm not responsible for your health you are,
so be smart with this information
and be a stringent filter, as we say.
Okay, very well, let's get started on the actual material. Somebody asked,
what is the role of moonlight and fire? I'm presuming they mean fireplace or candle or things
of that sort. In setting circadian rhythms, is it okay to view moonlight at night or will that wake me
up? Will a fire in my fireplace or using
candle light be too much light? Great question also offers me the opportunity to
share with you what I think is a quite beautiful definition of what light is in
a quantitative sense. So I've mentioned a few times the use of apps and light
meters and things to measure things like lux, which sometimes are also described
in terms of candelas. So those are the two units for measuring light intensity. Typically lux
LUX is the unit. And so before we go forward and discuss this many lux or that many lux,
I want to just tell you what a lux is because it relates to this question. One lux
lux is because it relates to this question. One lux equals the illumination of one square meter surface
at one meter away from a single candle.
I'm about to bet that it.
So somebody actually decided at some point
that the amount of illumination at one square meter surface,
one meter away from a single candle,
that equals one lux.
So when we talk about 6,000 lux of light intensity, or 10,000 lux of light intensity,
now you have a kind of a reference or a framework that would be the equivalent of,
you could think of it as 6,000 candles all with their light intensity shown on one square meter
from one meter's distance away. Or of course, if it was a different number of lux,
it would be a different number of candles. So you get the idea. Here's the great
thing. Turns out that moonlight, candle light, and even a fireplace, if you have one of these
roaring fires going in the fireplace, do not reset your circadian clock at night and trick
your brain into thinking that it's morning. Even though, if you've ever sat close to a fireplace or even a candle, that light seems
very bright.
And there are two reasons for that that are very important.
The first one is that these neurons in your eye that I discussed in the previous episode,
these melanopsin ganglion cells, also called intrinsically photosensitive ganglion cells,
those cells adjust their sensitivity
across the day.
And those cells respond best to the blue yellow contrast present in the rising and setting
sun, so-called low-solar angle sun, also discussed in the previous episode.
But those cells adjust their sensitivity such that they will not activate the triggers in the brain that convey daytime
signals when they view moonlight, even a full moon, a really bright moon, or fire.
Now this does raise an interesting kind of thought point, which is, you know, a lot of people
talked about lunacy and the fact that when there's a full moon out, people act differently
and behave differently.
There's a lot of lore around that.
There's actually a little bit of quality science around that that maybe we can address in the
future.
But, you know, the moonlight is typically not going to wake us up too much, except maybe
if the moon is really full and really bright, there's possibility for that.
So providing you're not going to burn down the structure you're in, you're not going to
burn down the forest, enjoy your fireplaces, enjoy your lights from candles, and those are perfectly safe without
disrupting your circadian rhythm.
Because we talked about just how crucial it is to avoid bright lights between the hours
of about 10 pm and 4 am, except when you need to view things for sake of safety or work
or so and so forth.
I also received a lot of questions about red light.
Now, I think I was asked those questions
because red light is used in a number
of different commercial products where these products
tend to include a sheet of very bright red lights
that one is supposed to view early in the day.
And there are various claims attached to these red light
devices that they improve mitochond red light devices that they improve
mitochondrial function, that they improve metabolism. I'm going to be really honest and I can't
name brands and I'm not going to name particular studies because what I'm about to say about these
studies is not particularly unkind, but let's just say that none of the studies that I've seen
except for one that I'll talk about in a moment
pointing to the positive effects of red light on the visual system
are published in blue ribbing journals. They tend to be published in journals that I had to work hard to find
I'm not sure what the peer review and stringency level is. Now, that's not to say red light isn't beneficial because there is one study in particular
that came from Glenn Jeffries lab at the University of college London. It was
published last year. Glenn has somebody that happened to know, is an excellent reputation,
excellent vision scientist. What this study essentially showed, and again this is a study that I
very much like the data and think it was done with very high standards. What this study shows is that viewing red light for a few minutes each morning can have
positive effects on mitochondria in a particular retinal cell type that tends to degenerate
or decline in function with age in humans.
And that cell type is the photoreceptor.
The photoreceptor is a type of cell in your eye
that sits at the back of the eye.
It's kind of some distance away from the gangling cells
and it's the cell that converts light information
into electrical signals that the rest of the retina
and brain can understand.
These are vitally important cells
without them people are blind.
And many people's vision gets worse with age.
In particular age-related macular
degeneration, but also related to some other factors, including photo risk receptor functionality
just getting worse with time.
And what Glenn showed was that red light flashes delivered in particular early in the day,
but not late in the day, can help repair the mitochondria.
Now this study needs more support from additional studies, of course. They are doing a clinical trial,
they did report on what I think it was 12 patients and so the work is ongoing,
but that was very interesting and it points to some potentially really useful
things about red light. However, most of the questions I got about red light for
sake of office hours were about the use of red light later in the most of the questions I got about red light for sake of office hours
were about the use of red light later in the day. So here's the deal. In principle, red light
will not stimulate the melanopsin retinal neurons that wake up the brain and circadian clock and
signal daytime. However, most of the red lights, in particular the red lights that come in these
sheets of these products that people are supposed to view them in order to
access a number of you know proclaimed health effects those are way too bright and would definitely wake up your body and brain
So if you're going to use those products and I'm not suggesting you do or you don't
But if that's your thing you would want to use those early in the day
Who knows you might even derive some benefit on mitochondrial function in these photoreceptors. But if you're thinking about red light for sake of avoiding
the negative effects of light later in the day and at night, then you want that red light
to be very, very dim. Certainly much dimmer than is on most of those commercial products.
Now do you need red lights? No, although red lights are rather convenient because you can
see pretty well with them on,
but if they're dim, they won't wake up the circadian clock. They won't have this dopamine disrupting thing that we talked about in the previous podcast.
So there's a role for red light potentially early in the day and for mitochondrial repair in the photoreceptors, there's a role for dim red light later in the day and at night.
red light later in the day and at night. So you're starting to notice a theme here which is that there's no immediate prescription of look at these lights. It's look at these lights potentially,
if that's what you want to do, at particular times of day and with particular intensities.
It brings us back to the blue light issue, which is so many people are obsessed with avoiding blue light,
but you actually want a ton of blue light early in the day and throughout the day, so don't
wear your blue blockers then, or maybe you don't wear at all. And it doesn't matter if you have blue blockers on, if the
lights are bright enough, then you're still going to be activating these cells
and mechanisms. I just want to add something since about the science behind the
blue blocker confusion. So these melanopsin retinal cells do react to blue light.
That is the best stimulus for one of these melanopsin retinal cells do react to blue light.
That is the best stimulus for one of these melanopsin cells, which led to the belief that
blue blockers would be a good thing for preventing resetting of the circadian clock at night and
deleterious effects of screens, etc.
However, the people that made these products fail to actually read the papers start to finish
or if they did did they didn't comprehend
a critical element which is that most of those papers early on took those neurons out and
put them in a dish and when they did that they divorced those neurons from their natural
connections in the eye. Turns out in your eye and my eye right now because that's what we
care about, these cells exist and these cells respond to blue light, but also to other wavelengths of light, because
they not only respond directly to light as they do in a dish, they also respond to input
from photo receptors.
So if you talk to anyone in the circadian biology field, they'll tell you, oh, yeah, this
blue light thing has really gotten out of control, because people assume that blue light is the
culprit, because blue light is the best stimulus.
That doesn't mean that blue light is the only stimulus that will trigger these cells.
So like many things, a scientific paper can be accurate without being exhaustive and
a lot of claims about products can be accurate but not exhaustive.
So blue light during the day is great.
Get that screen light.
Get that sunlight especially.
Get overhead lights.
I talk about all this in the previous podcast.
But at night, you really want to avoid those bright lights.
And it doesn't matter if it's blue light or something else.
And so there was a real confusion about the papers
and the data when most of those product recommendations
were made.
OK.
While we're on that topic, let's talk about light in other orifices of the body.
I made a kind of a joke about this the last podcast episode, but a couple of people wrote to me and said,
well, I've seen some claims that light delivered to the ears into the ears or the roof of the mouth,
or up the nose can be beneficial for certain settings or catian rhythms.
beneficial for certain settings or catarlythms.
No, not directly anyway. And this is a great opportunity for us to distinguish between
what is commonly called the placebo effect,
but a more important way to think about any manipulation,
behavioral or otherwise that you might do
is the difference between modulation and mediation.
There are a lot of things that will modulate your biology. Putting a couple of lights up your nose, please don't do this.
Might modulate your biology by way of the stress hormone that's released when you stuff those things up your nose.
Remember earlier, the previous podcast, I said that virtually anything will face shift to your circadian rhythm if it's different and dramatic enough. So the question is, is it the light delivered up the nose or through the ears or some of
their orifice that's mediating the process?
Is it actually tapping into the natural biology of the system that you're trying to manipulate?
And this is where I like to distinguish between real biology and hacks.
I don't like the word hack or, or frankly neurohacking or biohacking. I just don't like the term
because a hack is using something for it a purpose for which it was not intended, right?
But where you can kind of it's a kind of a cheat and that's not how biology works well.
So I try and distinguish between things that really mediate biological processes and things that modulate them.
There are a number of commercial products out there with some studies attached to them,
claiming that light delivered to the ears or wherever can adjust your wakefulness or adjust
your sleep.
I've looked at those papers again.
I'm probably going to lose some friends by saying this, but maybe I'll gain a few as well.
Not Blue Ribbon Journals, frankly.
Oftentimes read the small print.
There was a conflict of interest clause there related to commercial interests.
If somebody disagrees with me outright on this and consent to me, a peer reviewed paper
published in a quality journal about light delivered anywhere but the eyes of humans that
can mediate circadian rhythms, wakefulness, etc.
I'm more than happy to take a look at that and
change my words and stance on this and do it publicly, of course. But until then, you know,
I'm guessing that the proper controls were not done of adjusting for heat that could be delivered,
which can definitely shift circadian rhythms. We're going to talk about temperature and other things
like that. So light to the eyes, folks, is where these light
affects work in humans. In other animals, they have extracurricular photoreception in humans. No.
And just be mindful. I mean, I'm not trying to encourage people to avoid certain products
in particular, but just be mindful of this difference between modulation and mediation and
mediating a process through a hardwired or long-standing biological mechanism
is really where you're going to see the powerful effects over time. I also, as you've probably noticed,
I really tend to favor behavioral tools and zero-cost tools first in getting those dialed in before
you start plugging in and swallowing and, you know, putting things in various places,
just to really figure out how your biology works and explore that, unless there's, of course, a clinical need to take a prescribed drug, in which case, by all means,
listen to your doctor. Okay, a huge number of people asked me about what about light through
windows, and I actually did an Instagram post about this. Look,
through windows and I actually did an Instagram post about this. Look, setting your circadian clock with sunlight coming through a window is going to take 50 to 100 times longer.
If you want the date on that, I'd be happy to send you to the various papers that were described in the previous podcast
that Jamie Zitzer from Stanford and I have discussed also elsewhere.
But here's really the key thing with this.
Do the experiment.
You can download the free app Light Meter.
You can have a bright day outside or some sunlight.
Hold up that app, take a picture.
It'll tell you how many lux, now you know what lux are.
It will tell you how many lux are in that environment.
Now close the window.
And if you want, close the screen or don't open the screen,
you can do all sorts of experiments.
You'll see that it will at least half the amount of
Lux and it doesn't scare literally meaning let's say I get 10,000 lux outside, 5,000 looking out through an open window and then I close the
window and it's 2,500 lux. It does not mean that you just need to view that sunlight for twice as long if it's half as many looks. Okay, it's not like 25
100 lux means you need to look for 10 minutes and 5,000 lux means you look for
five minutes. It doesn't scale that way just because the biology doesn't work that
way. Best thing to do is to get outside if you can. If you can't, next best thing to
do is to keep that window open. It is perfectly fine to wear prescription lenses
in contacts. Why is it okay to wear prescription lenses and contacts. Why is it okay to wear prescription lenses
and contacts when those are glass also? But looking through a window, diminishes
the effect. Well, we should think about this. The lenses that you wear in front
of your eyes by prescription or on your eyes are designed to focus the light
on to your neural retina. In fact, that's what nearsightedness is, is when the image, because your lens doesn't work quite right,
the image falls in front of the neural retina, wearing a particular lens in
front of that focuses the lens onto your retina onto these very neurons so they
can communicate that to the brain. Costello is loving this, he's deep and
sleep, and if we maybe we could play him some tones and he'll remember it later based on the studies we're going to talk about in a little bit.
I don't know how we know if you remembered it or not, but prescription lenses are fine. In fact, they're great for this reason. They're actually focusing the light on to the retina.
So think about this logically and all of a sudden it makes perfect sense. Your glass window or your windshield or the side window of your car, it isn't optically
perfect to bring the image and the light onto your retina.
In fact, what it's doing is it scattering and filtering light in particular the wavelengths
of light that you want.
So if you live in a low light environment, lots of questions about this.
We talked about this the previous podcast, but just get outside for longer.
Or and or use really bright lights inside.
Okay, so let's think about why I'm making some of these recommendations, because I think it can
really empower you with the ability to change your behavior in terms of light viewing and other things,
depending on time of year, depending on other lifestyle factors.
The important point to understand is that early in the day,
your central circadian clocks and all these mechanisms are looking for a lot of light.
I mean, they don't have a mind of their own, but it needs a lot of light to trigger this daytime signal, alertness, etc.
And early in the day, but not in the middle of the day, you can some or add photons.
So there's this brief period of time early in the day when the sun is low in the sky, when your brain and body are expecting a morning wake-up signal, where let's say it's not that bright outside. Someone sent me a picture or a little movie of their walk in England, and it was pretty
overcast, and they were using light meter, and they said it's only about 700 lux, or
maybe even less.
And I said, well, stay outside longer, but when you get inside, turn on the lights really
bright and overhead lights in particular, because those will be best for stimulating these
mechanisms.
And that's because, at least for the first few hours of the day, you can continue to
sum or add photon activation of these cells in the eye and the brain.
In the middle of the day, once the sun is overhead, or even if you stay inside all morning,
and then you're in the circadian dead zone, which sounds terrible, and it is terrible, because you, it doesn't matter if you get a ton of artificial light, or even sunlight,
you're not going to shift your circadian clock, you're not going to get that wake-up signal.
And then in the evening, you want to think about this whole system as being vulnerable to even a
few photons of light, because your sensitivity to light really goes up at night. And I talked last time about how you can protect against that sensitivity
by looking at the setting sun and watching the evening sun,
even if it's not crossing the horizon around the time of sunset.
And that's because it adjusts your retinal sensitivity
and your melatonin pathway so that light is not as detrimental
to melatonin at night.
Think about the afternoon sunlight viewing as kind of a,
I think of it as kind of a Netflix inoculation.
It allows me to watch a little bit of Netflix in the evening,
although it's very hard to watch a little bit
of anything on Netflix.
It seems like there's some other neurobiological process
that going on there where I have to watch episode after episode
or after episode.
But in any case, you can protect yourself against
some of that bad effect of light at night by looking at light in the evening.
It really does adjust down the sensitivity of the system.
Okay.
I want to talk about seasonal changes in all these things as they relate to mood and metabolism.
So depending on where you are in the world, Northern hemisphere, Southern hemisphere, at the equator, closer to the poles, the days and nights are going to be different
lengths. That just makes sense. But that translates to real biological signals that impact everything
from wakefulness and sleep times, but also mood and metabolism. So here's how this works.
Now after seeing the previous episode of the podcast and paying attention here,
you are armed with the knowledge to really understand how it is that believe it or not every cell in your body is tuned to the movement of the planet
relative to the sun.
So as all of you know, the earth spins once every 24 hours on its axis.
So part of that day, we're spins once every 24 hours on its axis.
So part of that day were bathed in sunlight,
depending on where we are, the other half of the day
or part of the day were in darkness.
The earth also travels around the sun.
365 days is the time that it takes one year
to travel around that sun.
The earth is tilted, it's not perfectly upright. So the earth is tilted on its axis
So depending on where we are in that 365 day journey and depending on where we are in terms of hemisphere northern hemisphere or southern hemisphere
Some days of the year are longer than others. Some are very short. Some are very long
If you have the at the equator you experience less variation in day length and therefore night length.
And if you're closer to the poles,
you're gonna experience some very long days
and you're also gonna experience
some very short days,
depending on which pole you're at
and what time of year it is.
The simple way to put this is,
depending on time of year,
the days are either getting shorter or getting longer.
Now, every cell in your body adjusts its biology according to day length,
except your brain, body, and cells don't actually know anything about day length. It only knows
night length. And here's how it works. Light inhibits melatonin, powerfully.
If days are long and getting longer, that means melatonin is reduced.
The total amount of melatonin is less because light is more, therefore melatonin is less.
If days are getting shorter, light can't inhibit melatonin as much through the summing
of photon mechanisms that we talked about before, and that
melatonin signal is getting longer.
So every cell in your body actually knows external day length and therefore time of year by
way of the duration of the melatonin signal.
And in general, it's fair to say that in diurnal animals, meaning animals like us that tend
to be awake during the daytime and not nocturnal animals, which tend to be awake at night.
The longer the melatonin signal, the more depressed, not necessarily clinically depressed,
although that can't happen, but the more depressed our systems tend to be reproduction,
metabolism, mood, turnover rates of skin cells and hair cells all tend to be diminished
compared to the spring and summer months for some, northern hemisphere spring and summer
months, or the times in which days are very long and there's less melatonin that tends
to in almost all animals, including humans, more breeding, more hormone elevation of the hormones that stimulate
breeding, reproduction and fertility. Metabolism is up. Lippet metabolism, fat burning is up. Protein
synthesis is up. These things tend to correlate with the seasons. Now, some people are very, very
strongly tied to the seasons. They get depressed, clinically
depressed in winter. And light therapies are very useful for those people. Some people love the winter
and they're happiest in winter. And they feel kind of depressed in summer, although that is far more
rare. That doesn't mean depression cannot exist in the summer. But when we're talking about seasonal
depression, that tends to be true. It's more depression in winter.
Now, there's other things that correlate with seasonality.
Suicide rates tend to be highest in the spring,
not in the winter,
but that has to do with some of the more complicated
and unfortunately tragic aspects of suicide,
which is that oftentimes people will commit suicide
not at the very depths of their energy levels,
but as they're emerging from those depths of low energy.
So we'll talk about suicidality and mood disorders
in a later podcast season, meaning a month later,
but for now, just to understand that everybody
is going through these natural fluctuations,
depending on the duration of the melatonin signal.
Now, this might lead you to say, well, then I should just really get as much light
as I can all the time and reduce melatonin and feel great all the time. Unfortunately,
it doesn't work that way because melatonin also has important effects on the immune system.
It has important effects on transmitter systems in the brain, et cetera. So everybody needs to figure out for themselves how much light they need early in the day and
how much light they need to avoid late in the day in order to optimize their mood and metabolism.
There is no one size fits all prescription because there is a range of melatonin receptors,
there are a range of everything from metabolic types to genetic histories, family
histories, et cetera.
There is no one-size-fits-all prescription.
But by understanding that light and extended day length inhibit melatonin, and melatonin
attends to be associated with a more depressed or reduced functioning of these kind of activity,
driving, and mood-elevating signals,
and understanding that you have some control over melatonin
by way of light, including sunlight, but also artificial light,
that should empower you, I believe, to make the adjustments
that if you're feeling low, you might ask,
how much light am I getting? When am I getting that light?
Because sleep is also important for restoring mood, right?
So you need sleep.
You can't just crush melatonin across the board
and expect to feel good
because then you're not gonna fall asleep and stay asleep.
Melatonin, not incidentally, comes from,
is synthesized from serotonin.
Serotonin is a neurotransmitter
that is associated with feelings of well-being provided to proper
levels, but well-being of a particular kind, well-being associated with quiescence and calm
and the feeling that we have enough resources in our immediate kind of conditions.
It's the kind of thing that comes from a good meal or sitting down with friends or holding
a loved one or conversing with somebody that you really bond with.
Serotonin does not stimulate action.
It tends to stimulate stillness.
Very different than the neuromodulator dopamine,
which is a reward, feel good neuromodulator
that stimulates action.
And actually dopamine is the precursor to epinephrine, to adrenaline, which actually puts us into action. And actually dopamine is the precursor to epinephrine, to adrenaline, which actually
puts us into action. It's actually made from dopamine, right? So you can start to think
about light as a signal that is very powerful for modulating things like sleep and wakefulness,
but also serotonin levels, melatonin levels. And I talked about this previously, but I'll
mention once more that light in the middle of
the night reduces dopamine levels to the point where it can start causing problems with
learning and memory and mood, that's one powerful reason to avoid bright light in the
middle of the night.
Okay.
Seasonal rhythms have a number of effects, but humans are not purely seasonal breeders.
Unlike a lot of animals, we breed all year long.
In fact, there's a preponderance of September babies in my life,
not actual babies.
We build a born in September, which means that they were conceived in December.
Without knowing the details, we can fairly assume that.
And December, at least in the northern hemisphere,
it's 10 days, tend to be shorter,
and nights tend to be longer.
So clearly humans aren't seasonal breeders,
but there are shifts in breeding and fertility
that exist in humans,
but also much more strongly in other animals.
So seasonal effects vary.
Some of you will experience
a very strong seasonal effects.
Others of you will not.
I think everybody should be taking care to get adequate sunlight and to avoid bright
light at night throughout the year, if possible.
Throughout this podcast and in previous episodes, I've been mentioning neuromodulators, things
like serotonin and dopamine, which tend to buy a certain brain circuits and things in our
body to happen and certain brain circuits and things in our body not to happen.
One of the ones I've mentioned numerous times is epinephrine, which is a neuromodulator
that tends to put us into action, make us want to move.
In fact, when it's released in high amounts in our brain and body, it can lead to what we
call stress, or the feeling of being stressed.
Several people ask me, what's the difference between epinephrine and adrenaline?
Adrenaline is secreted from the adrenal glands, which sit right above our kidneys.
Epinephrine is the exact same molecule, except that it's released within the brain.
And so people use these phrases or these words, rather interchangeably.
Epi means near, we're on top of sometimes, and neph, neph, anytime you see nephron or
ephr, it means kidney, so it means near the kidney.
So epinephron actually means near the kidney, so it was used originally to describe adrenaline,
but epinephron and adrenaline are basically the same thing and they tend to stimulate
agitation and then desire to move.
That's what that's about, which brings us to the topic of exercise.
I've got a lot of questions about exercise.
What forms of exercise are best for sleeping well?
When should I exercise, et cetera?
There's a lot of individual variability around this,
but I can talk about what I know from the science literature
and what I happen to do myself. There are basically
two forms of exercise that we can talk about, although of course I realize there are many different
forms of exercise. There's much more nuance to this, but we can talk about cardiovascular exercise,
where the idea is to repeat a movement over and over and over continuously, so that'll be like running
biking, rowing, and cycling, this kind of thing. Or there's resistance
exercise where you're moving, lifting, presumably putting down also, things of progressively
heavier and heavier weight that you couldn't do continuously for 30 minutes. So cardiovascular
exercise is typically the more aerobic type exercise and resistance exercise
of course is the more anaerobic type exercise and yes there's variation between the two.
Most studies of exercise have looked at aerobic exercise because that's basically the thing
that you can get a rat or a mouse to do.
It's really weird about rats and mice.
They like to run on wheels so much that someone actually did this study, it was published
in science, they put a wheel, a running wheel in the middle of a field and mice ran to that wheel and
ran on the wheel.
They turns out that what they like is the passage of the visual image of the bars in front
of their face, which I find kind of remarkable and troubling because it seems so like trivial.
But anyway, they love aerobic exercise and so most of the studies were done on these
mice that love running on wheels.
Whereas, so far, it's been challenging to find conditions in which mice really like to
lift weights or will do it in a laboratory.
So any weight bearing exercise studies really have to be done in humans.
And since humans are what we're interested in,
there are some studies looking at these two things
and when they tend to work best.
Now, you will see some places
aerobic exercise is best done in the morning
and weight training is best done in the afternoon.
I think there's far more individual variation than that.
I think there are, however,
a couple of windows that the exercise science
literature and the circadian literature points to as windows related to body temperature
in which performance injury, in which performance is optimized, injury is reduced, and so
on.
And those tend to be 30 minutes after waking, and that probably correlates with the inflection in cortisol associated with waking, whether or not you've gotten light or not.
Three hours after waking, which probably correlates to the rise in body temperature, sometime right around waking, and the later afternoon, usually 11 hours after waking, which is when temperature tends to peak.
which is when temperature tends to peak. So, some people like to exercise in the morning,
some people like to exercise in the afternoon.
It really depends.
I think for those of us with very busy schedules,
it's advantageous to be able to do your training whenever
you have the opportunity to do it,
unless you can really control your schedule.
And so, I would never want these recommendations
to seem like recommendations.
What I'm really describing is some opportunities. 30 minutes after waking, three hours after
waking, or 11 hours after waking, has been shown at least in some studies to optimize performance,
reduce injury and that sort of thing. You really have to figure out what works for you.
A note about working out first thing in the morning. Last time we talked about non-photic
phase shifts. If you exercise first thing in the morning, your body will start to develop an
anticipatory circuit. There's actually plasticity in these circadian circuits that will lead you to
want to wake up at the particular time that you exercised the previous three or four days. So that
can be a powerful tool, but you still want to get light exposure because it turns
out that light and exercise converged to giving even bigger wake up signal to the brain and
body.
So you might want to think about that.
Some people find if they exercise late in the day, they have trouble sleeping.
In general, intense exercise, does that?
Whereas the kind of lower intensity exercise doesn't.
I found some
interesting literature that talked about sleep need and exercise. I found this
fascinating that if one is waking, not feeling rested and recovered from, and
yet sleeping the same amount that they typically have, it's quite possible that
the intensity of exercise in the proceeding two or three days is too high.
Whereas if one can't recover no matter how much sleep
they get, they're just sleepy all the time
and realize these things are correlated
that the volume of training might be too high.
Now, I'm not an exercise scientist,
we should probably get Andy Galpin or somebody else on here
who's really an expert in this kind of stuff.
I do realize as soon as anyone talks about exercise and nutrition publicly, they're basically
opening themselves up to all sorts of challenges because you can basically find support for
almost any protocol in the literature.
What I've looked at was two journals in particular, International Journal of Chronobiology, and Journal Biological
rhythms, excuse me, to assess these parameters that I mentioned just a moment ago, because
the studies tended to be done in humans.
They were fairly recent and they came from groups that I recognized as well as knowing
that those journals are peer-reviewed.
Many of your questions were about neural plasticity, which is the brain and nervous system's
ability to change in response to experience.
There was a question that asked whether or not these really deep biological mechanisms
around wakefulness, time of waking, sleep, etc.
Were subject to neural plasticity, and indeed they are.
Some of that plasticity is
short term and some of it is more long term. There's a really good analogy here, which is if you
happen to eat on a very tight schedule where every day, say at 8 a.m. noon and 7 p.m. is when you
eat your food, not suggesting you do this, but let's say you were to do that for a couple days.
is when you eat your food, not suggesting you do this, but let's say you were to do that for a couple of days.
After a few days, you would start to anticipate
those meal times where no matter where you were in the world,
no matter what was going on in your life,
about five to 10 minutes before those meal times,
you would start to feel hungry
and even a little agitated, which is your body's way
of trying to get you to forage for food.
And that's because of some peptide signals that come from the periphery from your body,
things like hypochreatinorexin that signal to the hypothalamus and brainstem to make you
active and alert and look for food and feel hungry.
So there's kind of an anticipatory circuit, that's a chemical circuit, but eventually over
time, the neurons, the neural circuits that
control hypocrete neorexan would get tuned to the neural circuits that are involved in eating and
maybe even smell and taste to create a kind of eating circuit that's unique to your pattern
to your rhythms. The same thing is true for these waking and exercise and other schedules, including all
trade-in schedules.
If you wake up in the morning and start getting your sunlight, you start exercising in the
morning or you exercise in the afternoon, pretty soon your body will start to anticipate
that and start to secrete hormones and other signals that prepare your body for the ensuing
activity of waking up or going to sleep. So if you get onto a pattern or a rhythm, even if that rhythm isn't down to the minute,
you'll find that there's plasticity in these circuits and it becomes easier to wake up early
if that's your thing or exercise it a particular day if that's your thing.
That's the beauty of neural plasticity.
A number of people ask what can I do to increase plasticity?
And that really comes in two forms.
There's plasticity that we can access in sleep
to improve rates of learning and depth of learning
from the previous day or so.
And there's this NSDR non-sleep deep rest
that can be done without sleeping
to improve rates of learning and depth of
retention, et cetera. So let's consider those both and you can incorporate these protocols if you
like. Again, these are based on quality peer-reviewed studies. First, let's talk about learning in sleep.
This is based on some work that I'll provide the reference for that was published in the journal
science. Excellent journal. Matt Walker also talks about some of these studies
done by others in his book, Why We Sleep.
These studies just to remind you
are structured the following way.
An individual is brought into a laboratory,
does a spatial memory task.
So there tends to be a screen
with a bunch of different objects popping up
on the screen in different locations. So it might be a bulldog's face, there might be a cat, a bunch of different objects popping up on the screen in different
locations. So it might be a bulldog's face, there might be a cat, then it might be an apple,
then it might be a pen in different locations. And that sounds trivially easy, but with time
you can imagine it gets pretty tough to come back a day later and remember if something
presented in a given location was something you've seen before and whether or not it was
presented in that location or a different location. If you've seen before and whether or not it was presented in that location or a different location.
If you had enough objects and change the locations enough, this can actually be quite difficult.
In this study, the subjects either just went through the experiment or a particular odor was released into the room while they were learning
or a tone was played in the room while they were learning.
they were learning, or a tone was played in the room while they were learning. And then during the sleep of those subjects, the following night and the following night,
so it was done repeatedly for several nights, the same odor or tone was played while the
subjects were sleeping.
They did this in different stages of sleep, non-REM sleep, and rapid eye movement sleep,
REM sleep. They did this with just the tone in sleep. If the subjects had the odor, but not the
tone, they did it with putting the tone. If they had the odor while learning. So basically,
all the controls, all the things you'd want to see done to make sure that it wasn't some indirect effects, a modulatory effect.
And what they found was that providing the same stimulus, the odor if they smelled an odor
or a tone, if the subject's heard a tone, while learning, if they just delivered that odor
or tone while the subject's slept, rates of learning and retention of information was
significantly greater. This is pretty cool. What this means that you can cue the subconscious brain, the asleep brain, to learn particular things,
better and faster.
So, how might you implement this?
Well, you could play with this if you want.
I don't see any real challenge to this, provided the odor is a safe one and it doesn't wake you up.
And the tone is a safe one and doesn't wake you up.
You could do this provided the odor and is a safe one and then doesn't wake you up and the tone is a safe one and doesn't wake you up.
You could do this by having a metronome, for instance, well, learning something, playing
in the background or particular music, and then have that very faintly while you sleep.
So you could apply this if you like and try this.
There are a number of groups I think now that are trying this using tactile stimulation.
So slight vibration on the wrist during learning and then the same vibration on the wrist during sleep.
It does not appear that the sensory modality, whether or not it's odor or auditory tone or tactile
stimulation, somatosensory stimulation, whether or not it matters. It's remarkable because it
really shows that sleep is an extension of the waking state.
We've known that for a long time,
but this really tethers those two in a very meaningful
and actionable way.
So I'll report back to you as I learn more about these studies,
but that's what I know about them at this point.
As long as we're there, we might as well talk about dreaming
because I got so many questions about dreams.
A couple of people want to ask me what their dreams meant.
Look, I don't even know what my dreams mean half the time.
I occasionally will wake up from a dream and remember it.
If you want to remember your dreams better, if you're somebody who has challenges
remembering your dreams, you can set your alarms that you wake up in the middle
of one of these 90 minute cycles, which toward morning tend to be occupied almost exclusively by REM sleep. Remember early in the night, you have less
REM sleep than later in the night. But you want to get as much sleep as you can, because
that's healthy, so I don't know that you want to wake yourself up. Some people find that
writing down their thoughts immediately, first thing in the morning, allows them to
relater spontaneously, remember their dream they had. There's some literature on that.
The meaning of dreams is a little bit controversial. Some people believe they have strong meaning,
other people believe that they can be just spontaneous firing of neurons that were active
in the waking state and don't have any meaning. There are good data to show that when you learn
spatial, new spatial
environments, that there's a replay of those environments, um, so-called place cells that
fire in your brain, only when you enter a particular environment, that those are replayed in sleep
in almost direct fashion to the way that, um, things were activated when you were learning
that spatial task. Dreams are fascinating. They're, you know, we're paralyzed during dreams,
which brings us to another question.
Somebody asked about sleep paralysis.
We are paralyzed for much of our sleep,
so-called atonia, so presumably,
so we don't act out our dreams.
Some people wake up and they're still paralyzed.
I've actually had this happen to me,
not very many times, but a few times,
and then they jolt themselves awake.
And it actually is quite terrifying, I can say, from personal experience to wake up, be
wide awake and you cannot move your body at all.
It's really quite frightening.
There are a couple things that will increase the intrusion of atonia into the wakeful state,
which essentially means you're waking up, but you can't move.
One is marijuana, THC.
I'm not a marijuana smoker.
I'm not a cop or I don't know the legality where you live,
so I'm not saying one thing or another about marijuana.
I'm just the fact that I had that experience
without marijuana means that it can happen regardless.
But marijuana smokers, for whatever reason,
maybe it has something to do with the cannabinoid receptors,
or the serotonin receptors downstream of the motor pathways.
I don't know.
I couldn't find any literature on this, but marijuana smokers report higher frequency of this kind of paralysis and wakefulness
as you transition from sleep to wakefulness.
I suppose probably one could learn to get comfortable with it.
For me, it was terrifying because I'm just used to being able to move my limbs
fortunately and I wasn't able to. And it's quite a thing, let me tell you. Okay, some other
questions about neuroplasticity. So the other form of neuroplasticity is not the neuroplasticity that you're amplifying
by listening to tones or smelling odors in sleep, but the neuroplasticity that you can
access with non-sleep deep rest.
So NSDR, non-sleep deep rest, as well as short 20-minute naps, which are very close to
non-sleep deep rest because people rarely drop into deep states of sleep during short naps
unless they're very sleep deprived.
NSDR has been shown to increase rates of learning when done for 20 minute bouts to match an
approximately 90 minute bout of learning.
So what am I talking about?
90 minute cycles are these all trading cycles that I've talked about previously.
And we tend to learn very well by taking a 90 minute cycle,
transitioning into some focus mode early in the cycle
and it's hard to focus and then deep focus
and learning feels almost like agitation and strain.
And then by the end of that 90 minute cycle,
it becomes very hard to maintain focus
and learn more information.
There's a study published in Cell Reports last year, Great Journal, excellent paper showing
that 20-minute naps or light sleep of the sort of non-sleep deep rest taken immediately after
or close to.
It doesn't have to be immediately after you finish the last sentence of learning or whatever
it is or bar to it. It doesn't have to be immediately after you finish the last sentence of learning, or whatever it is, or bar of music. But a couple minutes after transitioning to a period of
of non-sleep deep rest, where you're turning off the analysis of duration path and outcome has
been shown to accelerate learning to a significant degree. Both the amount of information and the
retention of that information. So that's pretty cool because this is a cost-free
drug-free way of accelerating learning without having to get more sleep, but simply by introducing these 20-minute bouts.
I would encourage people if they want to try this to
consider the 20 minutes per every 90 minutes of ultra-dying learning cycle. There you're incorporating a number of different neuroscience-backed tools, 90-minute cycles for focused
learning, it could be motor, it could be cognitive,
it could be musical, whatever.
And then, transition to a 20-minute
non-sleep, deep-rested protocol.
Just wanna cue you to the fact that in last episode
in the caption on YouTube, we provided links
to two different yoga-nidra non-sleep deep breast protocols
as well as hypnosis protocols that are clinically
backed from my colleague David Spiegel
at Stanford Psychiatry Department.
All those resources are free.
There are also a lot of other hypnosis scripts out there.
I like the ones from Michael Ceeley, S-E-A-L.
I think it's E-Y although maybe it's just L-Y.
You can find them easily on YouTube.
Clinical hypnosis scripts, meaning not stage hypnosis.
They're not designed to get you to do anything.
In fact, they're just designed to help rewire your brain circuitry.
Now, how does hypnosis work that way?
It says a lot to do with sleep because it engages neuroplasticity
by bringing together two things that normally are separate from one another. One is the alert focused, wakeful state where you activate
the learning, and then there's the deep rest where the actual reconfiguration of the neurons
and synapses takes place. Hypnosis brings both the focus and the deep rest component into
the same compartment of time. It's a very unique state in that way.
So hypnosis kind of maximizes the learning bout and the non-sleep deep rest bout and
combines them. But of course, that requires some guidance from a script or from a hypnotist,
clinically trained hypnotist. And it becomes hard to acquire detailed information. It's more about shifts in state, like fear to states of calm,
or smoking, quitting smoking, anxiety around a trauma,
to release of anxiety around a trauma,
rather than specific information learned in hypnosis.
Okay?
So hypnosis seems more about modulating the circuits
that underlie state as opposed to specific information
Although I would not be surprised if there weren't certain forms of hypnosis that could increase
Retention and learning of specific information, but I'm not aware of any of those protocols out there yet
Which brings us to the next thing about learning and plasticity, which is neutropics aka smart drugs
plasticity, which is Neutropics, aka Smart Drugs. This is a big topic. That sigh was a sigh of concern about how to address Neutropics in a thorough enough but thoughtful enough way. Look, I have a lot
of thoughts about Neutropics. First of all, it means Smart Drugs, I believe, and I don't like that
phrase because let's just take a step back
and think about exercise.
You just say, I want to be more physically fit. What does that mean? Does it mean? I would ask
for more specificity. I'd say, do you want to be stronger? Okay, maybe you need to lift
heavier objects progressively. Do you want more endurance? Very different protocol to access
endurance. Do you want flexibility? Do you want explosiveness or suppleness?
Huge range of things that we call physical fitness.
Maybe you want all of those.
If we were talking about emotional fitness, we would say, well, an ability to feel empathy,
but probably also to disengage from empathy because you don't want to be tethered to other
people's emotions all the time.
That's not healthy either.
You would think about being able to access a range of emotions, but for some people, their
range into the sadness regime is really quite vast, but their range into the happiness
regime might be kind of limited.
For other people who are in a manic state, it might be they can access all the happy stuff,
but not the sadder stuff.
So I'm speaking by way of analogy here,
but if we say, we're talking about cognitive
and cognitive abilities, we have to ask creativity,
memory, we tend to associate intelligence with memory.
I think this goes back to spelling bees or something.
The ability to retain a lot of information and just regurgitate information, which will get you some distance in some
disciplines of life, but it won't allow you creative thinking.
It's necessary for creative thinking.
You need a knowledge base, right?
You can't just look up everything on Google, despite what, you know, certain educators or
so-called educators say.
You need a database so that you have the raw materials
with which to be creative.
So necessary to have memory,
but not sufficient to be creative, right?
The creative could have a poor memory for certain things,
but certainly not for everything.
They can't have interrogate and retrograde amnesia.
They'd be like the goldfish that every time around the tank,
it can't remember where it's at.
I actually don't know that they've ever done that experiment,
by the way, but, you know, so notice respect to goldfish,
but, you know, so you get the idea, you've got creativity,
you have memory, you have the ability to task switch, right?
You have the ability to strategy develop and strategy implement.
So the problem I have with the concept of a
Neutropic or a smart drug is it's not specific as to what cognitive
Algorithm you're trying to engage. We need more specificity.
That said, there are elements to learning that we've discussed here before that are very concrete.
Things like the ability to focus and put the blinders on to everything else that's happening around you and in your head
mainly, right, distractions about things you should be doing could be doing or might be doing and
focus on what you need to do. And then that's required for triggering the acetylcholine
neuromodulator
that will then allow you to highlight the particular synapses that will then later change in sleep. So no newtropic allows you to bypass the need for sleep and deep rest. That's important to understand.
So I daydream about a day when people will be able to access compounds that are safe,
that will allow them to learn better, meaning to access information,
focus better, as well as to sleep better and activate the plasticity from the learning
belt. Right now, most neutropics tend to bundle a bunch of things together. Most of them
include some form of stimulant, caffeine. Episode two, I tell you more probably than you ever
want to know about caffeine, adenosine, and how that works. So refer there for how caffeine works.
But stimulants will allow you to increase focus up to a particular point.
If you have too little alertness in your system, you can't focus too much.
However, you start to cliff and focus drifts.
Okay, so you can't just ingest more stimulant to be more focused.
It doesn't work that way.
Most neutropics also include things that increase,
or a design to increase, aceto-calling,
things like alpha-GPC and other things of that sort.
And indeed, there's some evidence
that they can increase aceto-calling.
I refer you again to examine.com, the website,
to evaluate any supplements or compounds for their safety
and their effects in humans and animals.
Free website, as well as with links to studies.
So we need the focus component.
We need the alertness component.
The alertness component comes from epinephrine, traditionally from caffeine stimulation,
the acetycoline stimulation.
Traditionally comes from colon donors or alpha GPC, things of that sort.
And then you would want to have some sort of off switch
because anything that's gonna really stimulate your alertness
that then provides a crash,
that crash is not a crash into the deep kind of
restful slumber that you would want for learning.
It's a crash into the kind of,
let's just call it lopsided sleep,
meaning it's deep sleep, but it lacks certain spindles
and other elements of the physiology, sleep spindles that really engage the learning process
and the reconfiguration of synapses.
So right now, my stance on Neutropics is that maybe, maybe for occasional use provided
it's safe for you.
I'm not recommending it, but in general,
it tends to use more of a shotgun approach
than is probably gonna be useful
for learning and memory in the long run.
A lot of people ask about Modaphanil or Armodaphanil,
which was designed for treatment of narcolepsy,
so right there it tells you it's a stimulant.
And yes, there is evidence it will improve learning and memory.
Modaphanol is very expensive last time I check.
Armodaphanol I think is the recent release generic version of this that's far less expensive.
Most of these things look a lot like emphetamine and many of them have the potential for addiction
or can be habit forming. But more importantly, a lot of those things also can create metabolic
effects by disruption to insulin receptors and so forth.
So you want to approach those with a strong sense of caution.
Now there are the milder things that act as new tropics.
I mentioned some of them like alpha GPC.
Some people like Ginkgo.
Ginkgo gives me vicious headaches, so I don't take it.
So, you know, people really differ. Last podcast, I recommend magnesium 3 and 8 if you were exploring supplements.
I'm not recommending anything directly. I'm just saying if you're exploring supplements, magnesium 3 and 8 seems
among the magnesiums to be one of the more bioavailable and useful for sleep.
I recommended it actually to a good friend of mine.
It gave him, at very low dose,
he had stomach issues with it.
He just had to simply stop taking it.
So there's variability there.
He just gave him some stomach cramping
and just didn't feel good on it.
Stopped it, he felt better.
Other people take magnesium three and eight
and feel great.
I was asked, do magnesium need to be taken with or without food, day, time, or before sleep?
If you're going to go that route, it should be taken 30 to 60 minutes before sleep, because
it's designed to make you sleepy.
And I'm not aware that it has to be taken with food, but again, all of this has to be run
by your doctor, and this is your healthcare to govern.
Not, these are not strict recommendations, so look into it. But magnesium 3.8, most people I recommended to have benefit from it tremendously.
Some people can't tolerate it, so you have to find out.
There were a number of questions about other supplements designed to access deep sleep.
In part to access neural plasticity, but now I'm just sort of transitioning from neural
plasticity to
these compounds that can regulate sleep. One of them that I discussed at the end of the last
podcast I got a lot of questions about is Apigenin, API, G-E-N-I-N. Apigenin, if you look in the literature,
the way it works, is it increases some of the enzymes associated with GABA metabolism. It actually
GABA is an inhibitory neurotransmitter. It's the neurotransmitter that is increased
after a couple of drinks containing alcohol
and that shut down the forebrain.
Apogenin is a derivative of the chemomile.
I think the proper pronunciation of this
is matriccaria chemomila.
Although I always feel like I should be using a Spanish accent
whenever I say something like that.
Other related things that impact the GABA system and increase GABA are things like passion
flour, which is Pasi Flora Incurata.
I don't know why the Italian is that Italian?
Anyway, my Italian colleagues, please forgive me.
I have some very close Italian friends and colleagues in Genoa.
I butcher the Italian, sorry.
In any event, Appaginian and passion flower found in a lot of supplements designed to increase
sleepiness and sleep because, and they work presumably because they increase GABA.
Actually, they work on chloride channels rather than give you a whole lecture on membrane
biophysics and neurons, I'll just say that
when neurons are really active, it's because sodium ions salt rushes into the cells and causes them
to fire electrically. The cells tend to become less active as more chloride, which is a negatively charged
ion. It's probably taken some of you back to either the wonderful times or traumas of high school
physics.
The chloride is negatively charged, so it tends to make cells less electrically positive,
because it carries a negative charge.
And hyperpolarizes the neuron.
So, apogenin works through these, increasing the activity, these chloride channels, passion
flour works by increasing the activity, these chloride channels, and GABA transmission.
It tends to increase this inhibitory neurotransmitter that shuts off our thinking, our analysis of
duration, path and outcome.
So if you're going to explore these things, I suggest you at least know how they work.
You at least go to exama.com that you talked to your doctor about them.
Some people asked about serotonin for getting to sleep and staying asleep. Now, I understand
the rationale here. Just like I understand the rationale of taking something like McEunipurins or
Aldopa to increase dopamine, but sometimes what works on paper doesn't really work in the real world.
I personally have tried taking a supplement which was L-triptophan, which is the precursor to serotonin,
or 5HTP, which is designed to increase,
it is serotonin, basically.
You're just a one biochemical step away
from taking actual serotonin.
And I'll be honest, the sleep that I had
with increased serotonin by way of triptophan
or 5HTP was dreadful.
I fell asleep almost immediately.
You say, well, that's great.
And 90 minutes later
I woke up and I couldn't sleep almost for 48 hours. Now, that was me. I have a pretty sensitive system
to certain things and not to other things. Some people love these things. So you really have to
be thoughtful and explore them with that kind of awareness of being thoughtful and realizing that
what works for you might not work for everybody and what works for everybody might not work for you.
and realizing that what works for you might not work for everybody and what works for everybody might not work for you.
Okay, I'd like to continue by talking about the role of temperature in sleep, accessing sleep,
staying asleep and wakefulness.
But first, I want to tell a joke because I think this joke really captures some of the critical things to understand about any self-experimentation that you might do. So this is a story that was told to me by a colleague of mine who's now a professor of Caltech,
not to be named. So there's a scientist and they're in their lab and they're trying to understand
how the nervous system works. So they go over to a tank and they pick up a frog. They take the frog and they put it down on the table and they clap.
And the frog jumps.
So, they think for a while and they pick up the frog.
They go over the cabinet and they take out a little bit of a paralytic drug and they inject
it locally into the back leg.
Set it down and clap and the frog jumps. But it kind of like jumps to the side a little bit.
And they pick it up. They inject the paralytic into the other back leg.
They clap again. The frog jumps but it really doesn't jump well that time. It kind of drags
itself forward.
So they pick it up and they inject the paralytic into the remaining two legs.
They set it down and they clap.
The frog doesn't jump.
They go, oh my goodness, the legs are used for hearing.
Now they publish the paper.
Paper comes out in a great journal news releases releases. It's a really big deal.
Their career takes off.
20 years later, a really smart graduate student comes along and says, yeah, but that's loss
of function.
It doesn't really show gain of function.
So let's take a closer look.
So they repeat the first experiment and it checks out.
Everything happens the same way.
But then they take the frog and they inject a drug into all four legs that turns off the
paralytic, right?
It's an antagonist.
They set the frog down.
They clap and the frog jumps.
They go, oh my goodness, it's true.
The legs really are for hearing.
Now, first of all, I want to make the point that this is not
to illustrate that science is not a good practice.
It is.
We need to do loss of function and gain
and function experiments.
But just to show that correlation and causation
is complicated, you need to do a variety of control experiments,
and you really need to figure out what works for you.
And so while science can provide answers about what works under very controlled conditions,
it doesn't and can never address all the situations in which a given compound, a given practice, will or won't work.
And it's not just individual variability, it's that there are a number of different factors.
You, of course, know that light can activate and shift your circadian rhythm,
but so can exercise, so can food.
The last point I want to make is an important one, which is that no frogs were hurt in the
telling of this joke.
Okay, so let's continue.
I want to talk about temperature.
Temperature is super interesting as it relates to circadian rhythms and wakefulness and
sleep. First, let's take a look at what's happening to our body temperature across each 24-hour
cycle.
In general, our temperature tends to be lowest right around 4am and starts creeping up around
6am, 8am, and peaks sometime between 4pm and 6pm.
Now that varies from person to person,
but in general if we were to continuously monitor
or occasionally monitor temperature,
that's what we would see.
Now what's interesting is that even in the absence
of any light cues or meal cues,
we would have a shift, we would have an oscillation
or a rhythm in our temperature,
they would go from high to low.
This is why the idea that we're all 96.8 and that's our correct temperature. Forget that. That is no longer true.
It never was true. It depends on what time of day you measure temperature.
However, there is a range which is within normal range. I think most of us associate fever with somewhere around a hundred eight, a hundred and one, a hundred and three.
That's concerning and we will be very concerned if temperature drop too low as well.
The way that the temperature rhythm that's endogenous, that's within us and rhythmic, no matter what,
the way it gets anchored to the pattern I described before, being lowest at 4 a.m. and increasing
again around, you know, through the day until about 4 to 6 p.m. is by way of entrainment or matching
to some external cue, which is almost always going to be light, but also exercise.
Now you may have experienced this temperature rhythm and how quickly it can become unentrained
or it can fall out of entrainment.
Here's an experiment I wouldn't want you to do,
but you've probably experienced this before, where you wake up, it's sunny outside, and maybe
you have some email or some things to take care of, or maybe you didn't sleep that well
the night before, and so you stay indoors. You don't change anything about your breakfast,
you don't change anything about your within-home temperature or anything like that. And somewhere
right around 10 or 11 o'clock, you start feeling kind of chilled, like you're
cold.
Well, what happened was the oscillators, the clocks in your various tissues that are governed
by temperature and circadian rhythm are starting to split away from your central clock mechanisms.
So it's actually important that your temperature match day length.
Now there's another way in which temperature matches or daytime, excuse me.
There's also an important way in which temperature matches day length.
In general, as days get longer, it tends to be hotter out, not always, but in general, that's the way it is.
And as days get shorter, it tends to be colder outside.
So temperature and day length are also linked, metabolically they're
linked, biologically they're linked, excuse me, and atmospherically they're linked. For
the reasons that we talked about before about duration of day length and other climate
features and so forth. So one of the most powerful things about setting your circadian rhythm
properly is that your temperature will start to fall into a regular rhythm.
And that temperature has a very strong effect on things like metabolism and when you will
feel most willing and interested in exercising.
Typically, the willingness to exercise and engage in any kind of activity, mental or physical
is going to be when that rise in temperature is steepest, when the slope of that line is
greatest. That's why 30 minutes after waking is one of those key windows, as well as three
hours after waking, and then when temperature actually peaks, which is generally, generally,
about 11 hours after waking. So this is why we say that temperature and circuang rhythm
are linked, but they're actually even more linked than that.
We've talked before about how light enters the eye, triggers activation of these melanops
and cells, which then triggers activation of the superchiasmatic nucleus, the master circadian
clock.
And then I always say the master circadian clock informs all the cells and tissues of your
body and puts them into a nice cohesive rhythm.
But what I've never answered was how it actually puts them
into that rhythm.
And it does it two ways.
One is it secretes a peptide.
A peptide is just a little protein that floats
through the bloodstream and signals to the cells.
Okay, we're tuning your clock kind of like a little,
you know, watch store on or would tune the clocks.
But the other way is it synchronizes the temperature
under which those cells exist.
So, temperature is actually the effector of the circadian rhythm.
Now, this is really important because changes in temperature by way of exercise, by way of
eating, but especially by way of exercise can start to shift our circadian rhythm pretty
dramatically.
But let's even go to an a more extreme example. Nowadays there's some interest in cold
showers and ice baths. Not everybody is doing this. I
realize people seem to either love this or hate this. I
don't mind the cold dunk thing. I get regular about this from
time to time and I'll do it. I haven't been doing it recently.
It's always painful to do the first couple times then you get kind of used to it.
However, I've taken people to a cold donker, an ice bath, I have a family member who wouldn't get in literally past her toes,
it was like this is just too aversive for me. Some people really like the cold, people very
tremendously. Getting into an ice bath is very interesting because you have a rebound increase
in thermogenesis. Now you should know from the previous episode that as that temperature increases,
it will shift your circadian rhythm and which direction its shifts your circadian rhythm
will depend on whether or not you're doing it during the daytime or late in the day.
If you do it after 8 p.m., it's going to make your day longer, right? Because your body
and your central clocks are used to temperature going up early in the day and throughout the day
and peaking in the afternoon.
If you then increase that further or you simply increase it over its baseline at 8 p.m.
after temperature was already falling, even if it's just by a half a degree or a couple
degrees, or you do that with exercise, doesn't have to be with the ice bath, you are extending,
you are shifting forward, you are phased delaying your clock, you're convincing your clock and therefore the rest of your body that the day is still going, right?
You're giving it the perception, the cellular and physiological perception that the day is getting longer and you will want to naturally stay up later and wake up later.
Now you might say, wait, I do an ice bath late at night and I feel great and I fall deeply asleep. Well, cold can trigger the release of melatonin.
There's a rebound increase in melatonin.
So that could be the cause of that.
If you have to see what works for you.
But if you do the ice bath early in the day and then get out,
you will experience a more rapid rise or cold shower early in the day,
a more rapid rise in your body temperature that will phase
advance your clock and make it easier to get up early the following day. So for those of you
that are having trouble getting up, and this is going to almost sound laughable, but a cold shower
first thing in the morning will wake you up, but that's waking you up in the short term
because of a different mechanism, which I'll talk about in a moment, but it also is shifting your clock. It's phase advancing your clock in a way that makes you more likely to get up earlier the next day.
Okay, so in other words, increasing your temperature by getting in a nice bath or cold shower,
which or exercising, which causes a compensatory increase in body temperature.
Think about the normal pattern of body temperature.
Low around 4.35 AM starts to peak right around waking.
Starts, excuse me, starts to increase right around waking.
Then, steep slope, steep slope to a peak round 4 to 6 PM
and then drops off.
If you introduce an increase in body temperature
by way of cold exposure early in the day,
let's say 6 AM or 5 AM,
if you're, you know, masacres to get into a cold shower
at that time, more power to you.
It's going to make you want to wake up about half hour to an hour earlier the next day
than you normally would, whereas if you do it while your temperature is falling, it will
tend to delay and make your body perceive as if the day is getting longer.
These are phase advances and phase delays.
We're going to get into this in far more detail
when we talk about jet lag and shift work in episode four,
as well as other things.
But temperature is, again, it's not just one tool
to manipulate wake up time and circadian rhythm
and metabolism, it is the effector.
It is the way that the central circadian clock
impacts all the cells and tissues of your body.
If you wanna read further about this
and you're really curious about the role of temperature,
worked by Joe Takahashi,
who used to be at Northwestern University
and is now at UT Southwestern in Dallas,
incredible scientist,
and has really worked out a lot of the mechanisms
around temperature and circadian rhythms.
You can just Google his name and you'll see
a whole bunch of studies there.
I wanna talk about cold and cold exposure
because there's a great misconception about this
that actually you can leverage once you understand
how to use cold to either increase
thermogenesis and fat loss, metabolism,
or you can use it for stress mitigation and mood, and it really depends on
one simple feature of how you approach the ice bath or cold shower.
If you get into an ice bath or cold shower and you are calming yourself, you're actively
calming the autonomic nervous system, maybe through some deep breathing, maybe through
visualization, maybe you sing a song, you know, people do this stuff. They use various tools.
Some people find paying attention to an external stimulus is more helpful.
You know, thinking about something, not the experience of the cold.
Other people find that directly experiencing the cold and its most intense form and kind
of going into the cold, quote unquote, is the best way to approach it.
It really varies for people.
There's no right or wrong way to go about this.
But the goal of using cold exposure for stress inoculation and to raise your stress threshold
to be able to tolerate heightened levels of real-life stress, not the ice bath, but real-life
stress like work stress and relational stress, etc.
Is by suppressing the activation of the so-called sympathetic nervous system,
meaning the alertness or stress system.
That involves buffering or trying to resist the shiver response.
The shiver response is an autonomic response designed to generate heat, presumably,
and actually that is what it does, in order to counter the cold.
So when you use cold exposure and you're kind of muscling through it or you're learning
to relax within it as a form of stress inoculation, that's great and works quite well for that
purpose.
And there's a reason why cold exposure is used in a variety of forms of military stress
inoculation, most famous of which of course is the Navy SEAL Buds test, really, which is screening
procedure for becoming a SEAL involves a lot of exposure to cold water.
However, if you're interested in using cold exposure for fat loss and thermogenesis, you
want to do the exact opposite thing.
There was a paper published in Nature two years ago, which showed that cold-induced shiver,
the actual physical shiver, activates the release of a chemical in the body from muscle
called Sucanate, SUCCIN-ATE.
Sucanate travels in the bloodstream and then goes and activates a particular category of fat, not the typical kind of pink or white fat that we think of is like blubber in humans
So that the stuff that people seem to generally want less of
Except for those genetic freaks that seem to have none of it depending what they consume. Congratulations
Brown fat is called brown fat because it's actually dark under the microscope
Brown fat is called brown fat because it's actually dark under the microscope. It's rich with mitochondria and it exists mostly between the scapulae and in the upper neck.
And it generates thermogenesis and heat in the body.
It's rich with a certain category of adrenergic receptor.
Incidentally, epinephrine binds to adrenergic receptors.
Incidentally, epinephrine binds to adrenergic receptors. These brown fat cells increase metabolism.
It's called brown fat thermogenesis and cause fat burning, burning of other kinds of fat,
the pink and white fat.
So, what does this all mean?
This means if you want to use the ice bath in order to increase metabolism, shiver
away. If you want to use the ice bath
or cold shower in order to stress andoculate, resist the shiver and learn to stay calm
or, quote unquote, muscle through it. I don't know that anyone has ever really talked
about this publicly because I think the data are so new and I think that people assume that
the ice bath or cold exposure is just one thing. Here, I've talked about it three ways to shift your circadian rhythm depending on whether
or not you're doing it early in the day while your temperature is still rising or at its peak,
or after that peak in order to extend the perception of your day as continuing and make you want
to go to sleep later and wake up later.
Now, and then the third way, of course, is to either activate brown fat thermogenesis and increase metabolism. I suppose the fourth way would be to
increase stress tolerance or stress threshold.
Okay, but remember temperature is the effector of circadian rhythms. Light is the trigger.
The superchiasmatic nucleus
is the master circadian clock that mediates all these changes, also influenced by non-photic
influence like exercise and feeding and things of that sort, but temperature is the effector.
Now, you can also shift your circadian rhythm with eating. When you travel and you land in a
new location and your schedule is inverted 12 hours,
one way that we know you can shift your rhythm more quickly
is to get onto the local meal schedule.
Now that probably has to do with two effects.
One, or changes in temperature,
induce eating induced increases in body temperature.
Now you should understand why that would work.
As well as eating has this anticipatory secretion of
beta, of hypercretinorexin that I talked about it earlier.
So if this is getting a little too down in the weeds, don't worry about it.
I will get more into this in episode four of how to shift one's rhythm, but I would love
for people to understand that light and temperature are the real heavy duty levers when it comes
to moving your circadian rhythm and sleep times and activity schedules. And exercise and feeding can help, but really temperature and light,
with light being the primary one, are the most important when it comes to sleep and wakefulness.
Many people asked questions about food and neurotransmitters and how those relate to sleep, wakefulness,
and mood, which is essentially 25 hours of content for me to cover.
But I'm gonna try and distill out the most common questions.
We've talked a lot about neuromodulators like dopamine,
acetylcholine, and norepinephrine.
You may notice in those discussions
that the precursors to say serotonin is triptophan.
Triptophan actually comes from the diet.
It comes from the foods that we eat.
Tyrosine is the precursor to dopamine.
It comes from the foods that we eat.
And then once we ingest them,
those compounds are circulated to a variety
of different cells and tissues.
But it is true that our food and the particular foods
we can influence things like neuromodulator
levels to some extent.
It's not the only way because there are also enzymes and biochemical pathways that are
going to regulate how much tyrosine gets converted into dopamine.
And there are elements of the dopaminergic neurons, the dopaminerones themselves that are electrical
that have influence on this as well.
But there are a couple
fair assumptions that we can make. First of all, nuts and meats, in particular red meats,
tend to be rich in things like tyrosine. That tells you right there that because tyrosine is the
precursor of dopamine and dopamine is the precursor of norepinephrine and epinephrine that those foods tend to lend themselves
toward the production of dopamine and epinephrine and the sorts of things that are associated with
wakefulness. Now, of course, the volume of food that we eat also impacts our wakefulness. If we
eat a lot of anything, whether or not it's rib-eye steaks, rice, or cardboard, please donate cardboard.
Your stomach, if it's very distended, will draw a lot of blood into your gut and you will
divert blood from other tissues and you'll become sleepy.
So it's not just about food content, it's also about food volume, all right?
Fasting states generally are associated with more alertness up and effort and so forth and
Fed states are generally associated with more quiescence and relaxation
serotonin and and the kind of things that lend themselves more towards
sleep and less toward alertness
Foods that are rich and trip to fan tend to be things like white meat turkey also complex carbohydrates
So if you like you can start experimenting depending on what foods you eat. You can start experimenting with carbohydrate rich meals for accessing sleep
and more depth of sleep. This is actually something I personally do. I tend to eat pretty low
garbage during the day. I actually fast for until about noon, not because I have to work to do that,
but because I'd rather just drink caffeine and water during that time. And then sometime around noon,
I can't take it anymore, and I'm hungry, and I eat, and I try and eat low-carb-ish, unless I've worked out
extremely hard in the previous two hours, which I rarely do, although I do sometimes. And
that meal is then designed to prolong my period of wakefulness into the
late afternoon. And then sometime around dinner time, which for me is around 6.37pm, 8pm,
sometimes it's the least 9pm. I tend to eat things like white meat, fish, pastas, rice,
that kind of thing. My favorite food of all for accessing Trip to Fan is actually a
starch. It's actually a vegetable. That's the croissant, which is my favorite vegetable.
I don't eat those all the time, but I love them.
And they seem to increase dopamine as well.
Never actually done the mass spectrometry on a croissant, but they definitely
increase trip to fan and relaxation for me.
In all seriousness, low carbohydrate slash fasted, slash ketogenic diets tend to lend themselves
toward wakefulness by way of increasing epinephrine, nor epinephrine adrenaline dopamine and things
of that sort.
Carbohydrate rich meals, and I suppose we should talk about meals as opposed to diet, tend
to lend themselves more toward trip to fans, serotonin and more lephargic states.
There is very limited evidence that I am aware of that carbohydrate should be eaten at one
time a day as it relates to metabolism, et cetera.
I'm sure that will open up a certain amount of debate.
If you work out very hard and you deplete glycogen, then this all changes.
So some people are working out very hard into pleading glycogen, other people are not. That gets way outside the context of this
particular podcast. But yes, indeed, different foods can bias different neuromodulators, and
thereby can modulate our waking or our feelings of lethargy and sleepiness. There are a couple
effects of food that are independent, or I should say, a couple
of effects of eating, because the food won't do it when it's sitting across the table,
but of eating that are powerful for modulating circadian rhythm, wakefulness, et cetera.
And that's because every time we eat, we get eating induced thermogenesis regardless
of what we eat.
Now the eating induced thermogenesis and increase in metabolism,
which is an increase in temperature, really, is probably greatest for amino acid rich foods
like meats, but also other types of foods. It's a minimal increase in body temperature,
compared to say cold exposure or exercise. Now whether or not it's a quarter of a degree,
or a half a degree or a degree,
it really depends on the individual.
And of course, there are blood sugar effects.
There are things like whether or not you are type one
or type two diabetic, whether or not you're insulin resistant,
whether or not, like there's a kid who,
in turns on the podcast here, who's 17 years old,
and I'm convinced that he can eat anything and he just seems
to like burn it up and he's growing and every time actually the other day he walked into the other
room and two days later he walked out of the same room he came out in between of course but
and I was like you're he grew he was like you know but he's at that stage where he's just growing
food is going to affect a teenager very differently than it's going to affect a full grown person
he's just growing. Food is gonna affect a teenager very differently
than it's gonna affect a full grown person.
So, in general,
starchy carbohydrates, white meat, such as turkey,
some fish, increased trip to fan,
therefore serotonin, therefore more lethargic states,
more calm.
Meat, nuts, and there are probably some plant-based foods
that I'm not aware of and I apologize,
I should read up on this, that also a high entire scene that can increase things like
dopamine, nor epinephrine, epinephrine, alertness.
So you can vary these, however you like, most people I think are eating a variety of these
things in given meals, and there are other parameters of nutrition that are important, too.
Volume of food for the reason I mentioned before, the volume of food in the gut, less food
in the gut, whether that's empty or a small amount of food will tend to correlate with
wakefulness.
Large volumes of food of any kind will tend to correlate and drive the calming response,
and that's by way of this nerve pathway called the vagus.
We actually have sensory fibers in the gut that communicate to a little protrusion of neurons
that sit right next to the jugular called the no-dose ganglia, and O-D-O-S-E.
I'm like Costello, it's no-dose right now, he's all-dose.
No-dose actually means having many protrusions, and it's like kind of a lumpy collection of
neurons, a ganglia is just a collection of neurons, and then it goes into the brain stem,
and then forward in the brain to the areas
of the brain that are involved in production
of various neuromodulators.
So what we eat and the volume of food
are both signaling to the brain.
It's not just one or the other,
and then there's also this eating induced thermogenesis,
and now you know from the discussion about temperature that if you're eating early in the
day, you're tending to shift your rhythm earlier so that you'll want to wake up earlier
the next day.
If you're eating very late in the day, even if you can fall asleep after that, there's
a tendency for you to want to sleep later the next day.
Now this, of course, is all going to be constrained by when your kids need to eat and when you're
spouse needs to eat and when your friends need to eat, or if you live alone, or what other
things you're doing.
If you're like me and you kind of don't eat until noon, then eat sometime around noon,
and then I'm terrible about meals.
I just start eating the ingredients while I'm supposed to be cooking, and then eventually
they're all gone.
And I guess that's a meal.
It varies.
Some people are neuratically attached to a particular meal schedule.
Some people are not. I take my light exposure schedule far more seriously than I take my meal schedule, although in general I try and eat healthy foods for the most part. Cresson's included.
I was asked several times whether or not men and women or males and females differ in terms
of these neurotransmitter phenotypes and the rhythms of sleep and temperature.
You know, we could probably devote a whole month and we probably will devote an entire month
to what are called sex differences because those tend to be related to things we absolutely know
like XX or XY chromosomes or XYY in some cases or XX chromosomes as opposed to gender, sex, and karyotype, as we call it. Genetic makeup is crystal clear.
There are things that correlate with one or the other,
but it's complicated and it's not something
that's been explored in what I think is enough detail.
Actually, and recently, I guess it was about five years ago,
the National Institutes of Health made it a mandate
that all studies use sex as a biological variable and actually explore both sexes of mice,
both sexes of humans when doing any kind of study because there was a bias towards only
using male animals or male subjects prior to that time.
So a lot of data are now coming out, reviewing important sex differences that I think are
going to have powerful impact on health
practices, et cetera, response to drugs, response to different sleep schedules, et cetera.
Perhaps the most salient and obvious one is that during pregnancy, females experience a whole
range of endocrine and neuro-affects, and we definitely will devote a month to pregnancy and childbirth and child rearing. And for that, I'd really like to bring in some experts. I've got terrific colleagues
at Stanford and elsewhere that work on these things so that we can go into those in more
depth. So I'm not blowing off those questions. I'm just kind of pushing them down on the road
a little bit where I can give you a more thorough answer. So as we finish up, I just want
to offer you the opportunity to do an experiment.
We've talked about a lot of variables that can impact sleep and wakefulness. And in keeping with the
theme of the podcast, we are going to continue to talk about sleep and wakefulness and tools for
those and the science behind those tools as we go forward. But there are really just four simple parameters
that you have control over,
that you can immediately start to record
and take note of just to see how you're doing
with these things, with no judgment
or perhaps no change to what you're actually doing.
It might be interesting, just a suggestion,
to write down for each day when you went outside
to get sunlight and when you did that relative to waking.
So you would write down, the way I do this in my calendar
is I'll write down that, I don't get exact about it.
I might say, I woke up at 615 and then I,
it's all put a W615 and then SL for sunlight.
I sometimes get outside right away. Other times I'm less good at that and I'll go a W615 and then SL for sunlight. I sometimes get outside right away.
Other times I'm less good at that and I'll go out around, I don't know, say seven.
And for how long?
Maybe like 10, 15 minutes or so.
And then I'll put a little check it roughly the times that I ate my so-called meals,
although as I mentioned sometimes my meals are a bunch of small checks that just kind
of extend through the late hours of the day.
Yours might be more confined to certain times.
And then you might just take note of when you exercised, just put down an E for when you
exercise weight training or aerobic exercise.
And you might note when you might have felt chilled or cold if you do or you might have
felt particularly hot or if you woke up in the middle of the night when you might have felt chilled or cold if you do or you might have felt particularly hot or if you woke up in the
Millenite when you felt particularly hot. And then the last thing you might want to do is just write down if and when you did a
non-sleep deep breast protocol, NSDR protocol, that could be meditation, that could be yoga nidra, that could be hypnosis, anything that you're
using to deliberately
teach your nervous system how to go from more alertness to more
calmness in the waking state, even if it's waking up in the middle of the night and doing
an NNSDR protocol or in the afternoon or first thing in the morning to recover some sleep
and ability to perform DPO's that you might have lost from a minimal or poor night sleep.
So you're going to write down when you woke up, when you viewed sunlight, that might be
in the morning and the evening or just the morning, hopefully it's the morning and the evening, when you exercised, when
you ate your meals, and using a simple record keeping scheme like W for waking, SL for sunlight,
maybe you come up with a system where it's a check or an X or something for exercise,
this is not designed to make you neurotically attached to tracking all your behaviors and everything you do.
I, for instance, don't track what I eat in particular. I kind of know what works for me, and I just try and stay within that range.
But by doing this, you can start to reveal some really interesting patterns.
Patterns that no answer that I could provide you about any existing tool or protocol could, you know,
counter. It's really about taking the patterns of behaviors of waking and light viewing and
eating and exercise and superimposing that on what you're learning in this podcast and elsewhere,
of course, and what you already know. And trying to see where certain problems
or pain points might be arising. Maybe you're eating really late in the day and you're waking
up in the middle of the night, really warm. Well, now you would say, well, that could be
due to kind of an increase in temperature that is extending my day. Or maybe you start
to find that using cold exposure early in the day is great for you, but using it late,
if it's too late in the day, that's not great. Or if you're into the sauna or even like some people, including
myself, if I take a hot shower or sit in a hot tub or a sauna late at night, well, then
I get a compensatory decrease in body temperature and I sleep great provided I hydrate well enough
because that can be kind of a dehydrating thing to sit in hot, hot conditions. But if I do the sauna early in the day, unless I exercise immediately afterward, then I tend to get the temperature drop,
which makes sense because we get the sauna, you get vasodilation, you throw off a lot of heat,
and then you generally get a compensatory drop in temperature. If you do that early in the day,
that's right about the time that that temperature is trying to entrain the circadian clocks of your
body. That's what happens to me. Other people it might be slightly different. And some people have more
resilient systems than others. So I just encourage you to start becoming scientists of your own
physiology, of your own brain and body, and seeing how the various tools that you may or may not be
using are affecting your patterns of sleep, your patterns
of attention and wakefulness.
It's vitally important that if you do this, that you know that it's not about trying
to get onto an extremely rigid schedule.
It's really about trying to identify variables that are most powerful for you and that push
you in the direction that you want to go and changing the variables that are pushing
your body and your mind in the directions that direction that you want to go. And changing the variables that are pushing your body
and your mind in the directions that you don't want to go.
Self-experimentation is something that should be done
slowly, carefully, you don't want to be reckless about this.
And this is where I would say manipulating one or two variables
at a time is really going to be best as opposed to changing
a dozen things all it wants to really identify
what it is that's most powerful for you.
As always, thank you so much for your questions. We are going to continue to answer questions. I
certainly didn't get to all of them, but we tried to get to most all of the ones that were frequently
asked. Episode four of the podcast, I'm going to get into shift work, jet lag, and age dependent changes in sleeping and wakefulness and cognition.
So for those of you with kids, for those of you that are kids, for those of you with older
relatives or who might be older meaning, probably when you start to get into late 60s,
70s and 80s is when there's some marked biological shifts in temperature regulation and things
that relate to sleep.
And for those of you that travel, we're going to talk about jet lag.
The shift work discussion might seem only relevant to those that work nights, but actually
that's not the case.
Most people, because of the way they're interacting with devices, are actually in a form of
shift work now, where the days are certainly not nine to five so-called
bankers hours and then the lights are out at nine and they're asleep until you know five am.
Some people have that schedule and most people do not. So episode four we will go deeply into
shift work, jet lag, age dependent changes in sleep alertness and cognition and I will touch back
on a few of your questions but don't think that if your question wasn't answered during these office hours that we won't get to it,
I absolutely will at some point.
In addition to that,
several of you have graciously asked
how you can help support the podcast,
and we very much appreciate that.
You can support the podcast by liking it on YouTube,
by subscribing on YouTube,
by recommending the YouTube videos to others,
as well as subscribing
and downloading the podcast on Apple, where you can also leave a review and on Spotify, or
all three, if you like. You can also help us by supporting our sponsors. So check out some of
the sponsor links that were described at the beginning of the episode. And in general,
recommending the podcast to people that you know and that you think would benefit from the information would be terrific.
And as mentioned at the beginning of today's episode, we are now partnered with Momentus
Supplements because they make single ingredient formulations that are of the absolute highest
quality and they ship international.
If you go to livemomentus.com slash huberman, you will find many of the supplements that
have been discussed on various episodes of the huberman lab podcast and you will find
various protocols related to those supplements. As always,
I will be continuing to post on Instagram. You can expect another podcast episode
out next Monday about the topics that we've been discussing this month and
above all, thank you for your interesting science.
you