Huberman Lab - How Hormones Control Hunger, Eating & Satiety
Episode Date: April 19, 2021This episode I discuss how hormones from our gut, liver, pancreas and brain control our appetite--and the specific tools we can use to adjust those hormones in order to achieve specific goals. I expla...in the brain areas that control our desire to eat, and our desire to stop eating. I discuss a hormone we all can make that is regulated by UV-rays from sunlight that reduces our appetite. I also explain that when we eat controls our appetite and not the other way around (and how to leverage that fact). I describe how we are basically always eating until we reach a threshold level of fatty acids and amino acids in our gut and the factors that can alter that signaling and make us eat far more than we need. I also explain how insulin, glucose and glucagon work, why cholesterol is so key for ovary, adrenal, liver and testes function and how the ketogenic diet impacts glucose and thyroid levels. As always, I describe many tools: specific supplements, prescription compounds, specific types (and timing) of exercise to regulate hormones, specific timing and types of eating, ways to reduce sugar cravings by triggering release of the hormone CCK, and more. Note: A future episode will cover Thyroid hormone. Also, I mis-spoke when explaining POMC neurons. I said “P-M-O-C” but should have said “POMC”. Apologies. The name I gave for what POMC is, however, was correct: "proopiomelanocortin". Thank you to our sponsors AG1 (Athletic Greens): https://athleticgreens.com/huberman Supplements from Thorne https://www.thorne.com/u/huberman Timestamps (00:00:00) Introduction (00:06:59) Hunger: Neural & Hormonal Control (00:08:32) Chewing & Hunger (00:11:05) Siamese Rats Reveal the Importance of Hormones In Hunger (00:13:08) Neurons That Powerfully Control Hunger by Releasing Specific Hormones (00:16:28) Anorexia & Extreme Overeating (00:16:57) Why Sunlight Suppresses Hunger: a-Melanocyte Stimulating Hormone (a -MSH) (00:20:03) Blue-blockers, Injecting a-MSH: Instant Tan & Priapism (00:22:30) Ghrelin: A Hormone That Determines When You Get Hungry, & That You Can Control (00:24:40) Meal Timing Determines Hunger, Not the Other Way Around (00:27:20) Satchin Panda, Circadian Eating & Intermittent(ish) Fasting (00:29:35) How To Rationally Adjust Meal Schedules: The 45min Per Day Rule (00:33:02) CCK (Cholecystokinin): A Hormone In Your Gut That Says “No Mas!” (00:34:55) Eating For Amino Acids, Fatty Acids & Sugar (00:39:05) L-Glutamine: Stimulates the Immune System & Reduces Sugar Cravings (00:43:42) Things To Avoid: Emulsifiers; Alter Gut Mucosa & Nutrient Sensing (00:49:32) “A Calorie Is NOT A Calorie” After All (00:52:36) Insulin & Glucose: Hyperglycemia, Euglycemia, & Hypogylcemia (00:56:12) The Order Your Eat Foods Matters: Managing Your Blood Glucose & Glucagon (01:02:40) Movement, Exercise & GLUT-4 (01:04:50) Why Sugar Stimulates Your Appetite (01:05:40) Keeping Blood Sugar Stable With Specific Exercises, The Power Of Insulin Sensitivity (01:07:55) High-Intensity Exercise, Glycogen & Metabolism (01:10:28) Cholesterol, HDL, LDL & Glucose Management: Ovaries, Testes, Liver, Adrenals (01:15:00) Prescription Compounds That Reduce Blood Glucose: Metformin (01:16:45) Berberine: A Potent Glucose Buffer That Also Adjusts Cholesterol Levels, Canker Sores (01:22:05) Chromium, L-Carnitine, Ginseng, Caffeine, Magnesium, Stevia, Vitamin B3, & Zinc (01:24:34) Acids: Vinegar, Lemons & Limes & False Alkalinity (01:26:40) Ketogenic Diets (In Brief): Effects On Blood Glucose, Thyroid Hormones (01:28:10) Diabetes, Filtering Blood, Sweet Urine (01:31:08) The Power of GLP-1 & Yerba Mate For Controlling Appetite, Electrolytes (01:35:19) Summary & Notes About Thyroid, Estrogen, Testosterone (01:37:20) Zero Cost & Sponsor-Based Ways To Support The Huberman Lab Podcast
Transcript
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Welcome to the Huberman Lab podcast where we discuss science and science-based tools for everyday life.
I'm Andrew Huberman and I'm a professor of neurobiology and
Ophthalmology at Stanford School of Medicine. This podcast is separate from my teaching and research roles at Stanford.
It is however part of my desire and effort to bring zero cost to consumer information about science and science-related tools to the general public. In keeping with that theme, I'd like to thank
the sponsors of today's podcast. Our first sponsor is Inside Tracker. Inside Tracker is a personalized
nutrition platform that analyzes data from your blood and DNA to help you better understand your
body and help you reach your health goals. I've long been a fan of getting blood work done,
and the simple reason for that is that most of the things
that you want to know about your health,
such as hormones, metabolic factors,
blood sugar levels, et cetera,
can only be analyzed from blood.
And nowadays, there are also excellent DNA tests
that can also give you valuable information
about what's going on at the cellular, molecular, even the neural circuit level within your brain and body.
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This month, we're talking all about hormones.
Hormones are incredible, and they control so many processes
in the brain and body.
Last episode, we talked about the role of estrogen
and testosterone.
Today, we're going to talk about how hormones impact
feeding and hunger, as well as satiety, the feeling
that you don't want to eat or that you've eaten enough.
Now, it's important to understand
that hormones don't work alone in this context. Today I'm going to describe some hormones that have
powerful effects on whether or not you want to eat more or less or stop eating altogether.
But they don't do that on their own, they do that in cooperation with the nervous system.
So today I would say as much or perhaps even more than any other episodes, we're going to
hear a lot of biology, but there are multiple what I'm going to call entry points for tools
that you can apply in order to regulate your levels of hunger, your meal timing, your levels
of satiety of not wanting to eat more.
And many of this is actionable with behaviors, but of course we're also going to talk about
supplements and we're actually going to talk about a little bit of brain machine interface
devices that can actually be involved in manipulating these incredible things that we think of as hunger and appetite and satiety.
So the first thing that you need to know about the nervous system side, the neural control over feeding and hunger, is that there's an area of your brain called the hypothalamus.
It's in the forebrain, which tells you it's in the front of your brain,
and it's at the base of the forebrain.
Now, the hypothalamus contains lots of different kinds of neurons
doing lots of different kinds of things.
There are neurons in your hypothalamus controlling sexual behavior,
controlling body temperature, controlling circadian rhythms
that desire to sleep or be awake, even neurons controlling rage.
There are actually neurons that if we were to stimulate them would send you or anyone
into a rage.
They're just powerful control centers for the brain and body.
There's a particular area of the hypothalamus called the ventramedial hypothalamus.
And it's one that researchers have been interested for a long time now in terms of its relationship
to hunger and feeding.
And the reason is it creates these paradoxical effects.
What do I mean by that?
What they found was that sometimes lesioning or disrupting the neurons in the ventramedial
hypothalamus would make animals or people hyperfagic.
They would want to eat like crazy.
And other lesions in other individuals or animals would make them anorexic, it would
make them not want to eat at all, it would make food aversive. So that means that the
ventramedial hypothalamus is definitely an interesting control station for hunger and feeding
and satiety, but it doesn't really tell you what's going on at a deeper level. In fact,
it's a little bit confusing or paradoxical. It turns out that there are multiple populations
of neurons in there.
We're going to talk about those.
Some are promoting feeding and some are promoting
not feeding or not eating.
Now, the other neural component of all this
that you need to know about
actually has to do with your mouth.
So there's an area of your cortex.
So that's a little bit further up in your brain
called the insular cortex.
And it processes a lot of different kinds of information, mostly information about what's
going on inside you, so-called interoception.
The insular cortex has neurons that get input from your mouth, from the touch receptors
in your mouth.
And insular cortex has powerful control over whether or not you're enjoying what you're
eating, whether or not you want to avoid what you're eating, whether or not you've had enough
or whether or not you want to continue eating more.
And that has to do, believe it or not,
with the touch or sensation of eating.
I'm very familiar with this.
I'm one of these people I love eating so much
that I just like the mere act of chewing.
You know, I like celery sticks enough.
I'm not crazy about them, but you know,
they taste fine to me and I like chewing on celery sticks
But I actually just like chewing on them. I could eat all day long except that it's not healthy to do that
But the mere act of chewing for me is very pleasurable people who chew gum feel this way as well and
Just as a point about gum or chewing if you choose something like celery or cucumber slices or chew gum provided it doesn't have any sugar or a colorate content
It's not going to drive increased hunger that generally isn't the case
But if you eat something with sugar as we'll find out it has a very specific action in the insular cortex and in other areas of your nervous system
That promotes the desire to eat more
But the key point right now is to know you got these two brain brain areas, the ventramedial hypothalamus, that's involved in hunger and
lack of hunger, sort of an accelerator and a break on feeding, and you have this
insular cortex that gets input from your mouth and cares about chewing and the
consistency of foods, and all sorts of interesting things that are just very
tactile. And I think most people think about the touch receptors on, excuse me,
the taste receptors on the tongue, but we often don't think about the touch or tactile essence of
food. The thing that comes to mind just now is I've gone to sushi several times and some
people really like the urchin. I don't like the urchin. There's something about it that
kind of creeps me out about the consistency. Other people love it. So it's highly individual
and it's probably learned and there's some probably cultural background to this. If you were raised eating urchin,
some people love that consistency or that touch.
So touch has a lot to do with whether or not you want to eat
or not.
Now, let's get back to the venture media hypothalamus.
Sometimes it makes animals or people want to eat more,
sometimes less.
So what's going on there?
There's a classic experiment that was done
in which researchers took two rats
and so-called parobios to them to each other.
What that meant is that they did a little surgery
and they linked their blood supply
so that they were forever physically linked to one another
and could exchange factors in the blood.
But their brains were separate, their mouths were separate
and they essentially did everything separately
except that they were linked to one another.
So they'd walk together and go to the same places in order to do it.
This parabiosis experiment revealed something really important.
When they lesioned the venture medial hypothalamus in one of the rats that was connected to the
other rat, that rat got very, very fat.
It's just really obese, huge rat, super rat, jumbo rat.
The other one, however, got very thin.
It actually lost weight, despite consuming the same amount of food that it had prior to
the other one getting the lesion.
So what does this tell us?
This tells us that there's something in the blood that's being exchanged between the
two animals because it was their blood supply that was linked, and that tells us that there's
hormone or endocrine signals that
are involved in the desire to eat and hunger and appetite.
Next we're going to talk about what those endocrine signals are, and then I'm going to immediately
point to some entry points that you can use, and you can use these even if you're not
parabiosed to anything, and that can allow you to time your meal frequency and predict when you're going
to be hungry or not, as well as a drive up appetite.
Believe it or not, there are people out there who are trying to eat more, although I think
far many more people are trying to eat less because nowadays, you know, the data just
point to the fact that there is essentially an epidemic of diabetes, type two diabetes
and obesity.
And most everyone agrees now that
maintaining a healthy body weight and body weight composition is one of the best paths
to longevity and to just feeling very good and actually being able to think cognitive
functioning is actually linked to levels of adipose tissue and so forth. So let's talk
about the endocrine factors that regulate feeding hunger and tired.
One of the really exciting things to emerge in the science of feeding and appetite in
the last 20 years is the discovery of another brain area, not just the ventramedial hypothalamus,
but it's an area of the brain called the arqueous nucleus.
And the arqueous nucleus has some really fascinating sets of neurons that release even more
incredible molecules and chemicals into the blood.
These chemicals act as accelerators on feeding an appetite or breaks.
The really cool thing is that you can actually control these molecules through simple behaviors.
Once you understand what these molecules are, you'll start to understand why that's the case and the control points that you have right now in order to control your
appetite in either direction, increase or decrease. So, first of all, there are a set of neurons
in this arqueuit nucleus called the PMOC neurons. Okay, I don't want to get into what the acronym
stands for, but I'll do it anyway. It's the pro-opio-malana-cortin system, okay?
So these are PMOC neurons, pro-opio-malana-cortin.
And if you heard malano, that should tell you
it has something to do with pigmentation in skin cells
or in hair cells, pigmentation of some sort,
because of melanin.
Last episode, I talked a little bit
about the relationship between light, dopamine,
and melanin. So you should already be thinking, wait, melano means it probably has something
to do with that system. And indeed it does. Now, the palm-seen neurons make something called
alpha-MSH. Melanostite stimulating hormone. Alpha-malanocyte stimulating hormone.
If you don't want to remember any of the other acronyms in terms I've talked about this
episode so far, do try and remember MSH, okay?
Mouse Sam Hamster, MSH, okay?
MSH reduces appetite and it's a powerful molecule, all right?
So just put that on the shelf. MSH reduces appetite.
Now there's another population of neurons
in the arqueot nucleus called the AGRP neurons.
And there I'm truly not gonna read you
what that stands for,
because it's related to the malstrain.
It was first identified in,
but humans have these cells as well.
But AGRP neurons,
the AGRP neurons stimulate eating and anytime you are
approaching food or you feel some excitement about food or anxiety because
some people actually experience a kind of heightened anxiety. Some people actually
get a little bit of a resting tremor before they eat even if they don't have
any sort of eating disorder. There's kind of a ramping up of autonomic activity. That's largely due to the activity of these AGRP neurons.
So the activity in these AGRP neurons goes way up when animals or people are starved.
And I don't mean starved for long periods of time, but I mean when they haven't eaten
for a while.
And the activity of MSH, the release of MSH, goes up when we've eaten. However,
there are other things that will stimulate the release of things like MSH. So just briefly,
the experimental evidence, if you kill AGRP neurons, animals, and people stop eating.
There are people of lesion. They just stop eating. They become anorexic. That's actually,
I know you're familiar with anorexia as a clinical term, but that's actually
a term that's used in the scientific literature about a pattern of behavior, okay?
As well as a clinical term, of course. If you were to stimulate the AGRP neurons,
animals or people eat like crazy. They will eat to the point where they burst, which just
sounds horrible, but it just tells you this is the accelerator on eating.
And yes, as relationship to the venture media hypothalamus, I talked about earlier, but I don't
want to go back there just yet.
We will circle back.
So melanocyte stimulating hormone, such an interesting hormone, this thing can shut down
the desire to eat.
The melanocyte stimulating hormone is released from the medial pituitary.
We talked about the pituitary last time.
This is a gland that is very closely positioned to the hypothalamus.
Actually, some of the hypothalamus neurons actually project their neural connections directly into the pituitary to release things like gonatropins and luteinizing hormone. Stuff we talked about last time in reference to testosterone and estrogen.
But MSH is released from the medial portion of the pituitary.
And it stimulates the desire to not eat, to cease eating.
What's really interesting is that melanocyte stimulating hormone is activated by ultraviolet
light. And it's not activated by ultraviolet light.
And it's not activated by ultraviolet light to the skin
or directly to the pituitary.
It's activated by ultraviolet light to the eyes.
Now, if you've been watching this podcast
or listening to this podcast for any period of time
or you've heard me on other podcasts or you follow my Instagram,
I am a big fan of this whole thing of getting morning light
in order to synchronize circadian rhythms, et. of wedding light in the middle of the night.
This is yet another reason why getting ample light, ideally sunlight, but it could be other
sources of UV light to the eyes, stimulates MSH. This has been shown over and over again,
and keeps the desire to eat or appetite in check in healthy ranges.
This is also why in the spring and summer months, animals and people eat less.
Now for hibernating animals, it's different because the bear hibernate, actually bears
don't truly hibernate technically by scientific criteria, they don't hibernate, but they
go into a kind of torpor.
The hibernating animals, they don't eat much because they but they go into a kind of torpor. The hibernating animals,
they don't eat much because they're in burrows or dens or they're just wrapped up in a little
ball or whatever it is that hibernating animals do. So they're of course going to eat far less
in the winter, but that's a unique scenario. We are not hibernating animals, but humans generally
have greater appetite in the cold winter months. It's not just because of the holidays and the
abundance of food that we're presenting ourselves with, but when we get a lot of sun, our appetite is reduced or at least
it's easier to control. And that is due in part because if you're getting ample sunlight
to the eyes, it's converted into a signal for the MSH neurons, the neurons that release
MSH, excuse me, these palm-seen neurons release MSH.
And then MSH can bind its receptors and can keep the break on appetite in check.
So the takeaway tool from this is make sure you are getting enough light, not just in
the morning, but throughout the day.
And yes, it has to be light to your eyes.
And blasting your eyes with sunlight or artificial light to the point where it's damaging or painful won't accelerate or improve this process.
It's about getting photons ultraviolet light to the eyes consistently throughout the day.
That's best accomplished by not wearing sunglasses provided you can do that safely and if you
don't have access to enough sunlight, then you can do this with artificial light.
This also points again to our old friends, the Blue Blockers.
Many people know I'm not a huge fan of Blue Blockers, especially not during the daytime
because they block a lot of the UV and shorter wavelength light that you want and need to
create alertness, but also to create release of MSH from the medial pituitary. Now, there are people out there subcultures
that actually inject MSH, that are taking MSH
or things similar to it.
I am not suggesting people do that,
but there are three main consequences of doing that.
First of all, it reduces appetite, no surprise there,
and they're actually using it as a dieting drug. This is kind of in the underground. I don't know what the legal status is, and again, I'm not
promoting that people do it. Two, it makes them very, very tan, which makes sense, right?
Melanocyte stimulating hormone. And the third is it purportedly, never tried it, purportedly
sends libido through the roof to the point where it's actually distracting for other activities
It actually can create pre-opism
Which is a kind of chronic erection in males to the point where actually can be physically damaging to the genitalia
So this is a drug of or a I don't know whether or not to call it a drug
It's a it's a substance that one can regulate with healthy levels,
with sunlight and perhaps artificial UV light. I have not heard much about treatments for
obesity involving getting ample sunlight or getting ample UV light, but to me the logic
is just very clear. And so if you're pursuing those avenues, you certainly should talk
to your physician, but you might want to think about how some of those logic hangs together.
Absolutely fascinating hormone, I think most people aren't aware of it.
And the subcultures that are aware of it are using it to very particular endpoints, and
they're using it at super physiological levels.
That's enough about that, because I really don't know.
I've talked to a few people in research, believe or not, for this podcast. I reach out to a few people and ask whether or not these side effects
in air quotes. I've heard about our true and indeed they're true. But again, that's super
physiological. Controlling MSH, it's actually alpha MSH levels through viewing ultraviolet light
seems like an interesting and mechanistically logical thing to do if your
goal is to keep appetite in check.
So MSH inhibits hunger.
Next let's talk about a hormone peptide that activates hunger.
And this is a really interesting one because it relates to when you get hungry, in addition
to the fact that you get hungry at all.
And it's called Grellen. It's spelled GHR E L I N. Grellen is released actually from the GI
tract. And its main role is to increase your desire to eat. And it does that
through a variety of mechanisms. Part of that is to stimulate some of the brain
areas, the actual neurons,
that make you want to eat. In addition, it creates food anticipatory signals within
your nervous systems. You start thinking about the things that you happen to like to eat
at that particular time of day. This is fascinating. Grilling is sort of like a clock, a hormonal
clock that makes you want to eat at particular times.
Now the signal for Grelin is reduced glucose levels
in the blood.
We're going to talk a lot today about glucose and insulin
ways to manage glucose and insulin.
But for now, the simple version of this
is you normally want your glucose to be
in a kind of modest range.
And I'll explain what that
range is in a little bit.
But if it drops too low, Grellen is secreted from your gut.
It activates neurons in your brain at various locations, including the PMOC neurons and
the other neurons of the arqueuit.
It also activates the VMA, in particular ways, and it might even activate some of these neurons that are in the periphery in your mouth that actually make you kind of salivate and want to eat.
We all know about the famous Pavlovian experiments of Pavlogs dogs. They start salivating to the bell after the bell was presented with food.
You remove the food and then just the bell can stimulate the salivation. We become Pavlovian at times. But rarely is it ever discussed what the neural pathways for that are.
And it turns out that these hormones that are secreted from the gut
can stimulate the neurons to create a sensation
and a desire for certain foods at certain times of day.
You've done this experiment.
If you are somebody who eats breakfast
at more or less the same time each day, let's say
8 a.m. plus or minus 20 minutes and then you eat lunch, 1230 plus or minus 20 minutes.
Or let's say you're somebody like me who typically skips breakfast and just eats lunch
usually around 1130 or 12 or something like that.
Your grell and secretion will start to match when you typically eat.
It does that, and it's able to override the low levels of glucose in your bloodstream
because the Grelan system also gets input from a clock in your liver that is linked to
the clock in your hypothalamus in your brain.
What this means is, if you eat at regular meal times, you will start to get hungry a few minutes
before those meals times.
If you've ever wondered why your stomach
kinda starts to growl because it's a particular time of day,
you're like, oh, I must wanna eat.
Well, that's grelin.
And for those of you that don't know why your stomach growls,
I'll also tell you that today.
It's actually really interesting.
It's not at all what you expect,
and it's not just the gurgling of liquids in your stomach. That's not what it is. It's actually a muscular phenomenon.
So, grellen is secreted as a kind of food anticipatory signal to get you motivated to go eat at
regular times. So, nowadays, there's a lot of interest in intermittent fasting. There's also a lot
of interest in just what meal plans
and schedules and what to eat in general in order to maximize one's health and well-being
and people have all sorts of cosmetic reasons and brain reasons and metabolic reasons for
wanting to control this kind of stuff. So let's make it really simple by first looking at
the extremes. Some people need to eat every two or three hours. They
forgive this. I need to eat every two or three hours or else their blood sugar drops. In
general, blood sugar doesn't drop so low that they truly need to eat in order to alleviate
a blood sugar issue. Although sometimes that can happen. Some people are truly hypoglycemic,
low blood sugar. But most people as the blood sugar starts to head down towards
the low-ish ranges, growing as secreted.
And so for those people not eating on the clock is very disruptive to them because it activates
these neurons in the brain.
For people who eat once a day or twice a day, or tend to shift their meals, you know,
they might eat a lot, but during a limited, so-called feeding window,
it's kind of interesting humans now, eat, and talk about foods in ways that for years,
I used to hear about in classes and courses and research lectures about feeding animals,
restricted feeding windows.
We owe a great deal of gratitude to Sachin Panda, who was a colleague of mine when my lab was in San Diego at the Salc Institute, who really is one of the pioneers of this restricted feeding window work and
has done a beautiful work.
He has a book that's excellent called the circadian code that I highly recommend.
And he's done a lot of important work on neurons in the retina that control circadian timing,
but also the relationship between feeding windows and health.
And he's sort of the major proponent out there,
among the major proponents, I should say, of circadian eating,
that means eating during the daytime, not at night,
or intermittent fasting, restricting feeding windows
to anywhere from four to six to eight hours.
I'll use myself as an example of the transition
from regular feeding schedule to more intermittent-ish fasting,
although I don't really fall into true intermittent fasting.
So I was one of these people that just got so accustomed to waking up and eating about
an hour after I woke up, that to go from eating every three or four hours to eating twice
a day, lunch and dinner, maybe a couple snacks in the afternoon or something, at first was
excruciating.
I remember thinking like,
this is really brutal, pushing out, feeding.
I didn't think I could exercise unless I had eaten first.
We now know that during most all forms of exercise,
unless you're really focused on optimal performance,
like you've got a hit key lifts
or you have to sprint at your maximum speed,
and maybe even then,
that you can exercise fast,
it just fine, because you're mainly relying on sources
like glycogen from the liver, some undigested food sometimes,
as gross as that my seam, it's true,
as well as body fat if the exercise belt is extremely long.
But what that means is that if you suddenly go from eating
on a very regular schedule to skipping a meal,
or pushing your meal timing out, or shifting it at all, means is that if you suddenly go from eating on a very regular schedule to skipping a meal
or pushing your meal timing out or shifting it at all, you're going to have grellen in
your system.
And that grellen is going to stimulate the desire to eat by acting at the level of your brain.
And it is indeed, at that point, just mental.
When we hear about just mental, just physical, it's really kind of the same thing because
it's all chemicals, brain, and body.
But it's the stimulation of neurons that anticipate feeding.
You're stimulating the arqueuit nucleus neurons that make you want to eat those agr-p neurons.
So growing stimulates the agr-p neurons, which makes you want to eat.
So what can you do with this?
What this means is, if you want to start shifting your feeding schedule to one where you're
not eating quite as frequently, and there are some advantages to that that aren't just
in the biochemistry and health, related, you know, cellular health related things, but some of them include not having
to think about or buy food, right? You actually don't have to think about food all day if you're not
eating so often. The other is it gives you a far more social flexibility, right? You can go to a
new meeting if you have to or you can go out to dinner at a particular time.
I guess it makes it kind of tough if you want to meet somebody for breakfast because then
you're the door, who's just like sipping black coffee and like refusing everything.
But anyway, I've been that door.
So it's one of those things you just kind of work with.
But the fact of the matter is, Grellen's secretion, because of its relationship to the nervous
system, can be shifted by about
45 minutes per day.
Now it's going to vary.
Some of you have more so-called willpower, you know, but if you really want to just start
pushing that first meal out or shifting it in any direction, some people might want to
eat in the early part of the day and not in the evening, trying to shift the meal times
out, the spacing by about 45 minutes is what the,
the neural circuits that link the grellin system
to the neural circuits, the control feeding,
really can handle because it's a form of neural plasticity.
And so what this would look like is,
if you normally eat breakfast at eight,
a clock plus or minus 20 minutes,
and you wanna start eating your first meal at noon,
you would take maybe four or five days
and just start pushing the meal out by about 45 minutes
to an hour each day, so it's not quite as painful.
Or you can just take the plunge and just do it all at once.
I have a colleague who was a neurosurgeon at Stanford
came up through my lab, he's now at NeuralLink,
and he has a great practice.
He keeps his Grelan system at random.
What he does is he skips one meal per day
and he makes his external schedule dictate that. does is he skips one meal per day and he makes his
external schedule dictate that. So sometimes he skips breakfast, sometimes he
skips lunch, sometimes he skips dinner, he just skips one of the three major meals
per day. And in doing that, the grueling system is always kind of kept off
kilter. And it probably also allows him to have a lot of neural flexibility,
what we call top-down control, just the knowledge, oh, you know, the hungram
feeling isn't necessarily hypoglycemia.
And in his case, it's almost certainly not.
And therefore, what I'm feeling here is an activation of these agirp neurons.
And therefore, I can push my meal schedule around, however I want.
Now, I should mention that top down mechanisms are powerful belief motivation.
These things can really shift neural circuits.
We're going to talk more about that a little bit later.
But there are also people who are genuinely hypoglycemic and then need to take really good control of their blood sugar levels and try and keep them stable.
And so of course, you want to do what's medically safe for you. I'm not at all recommending that people that suffer from
hypoglycemia suddenly, you know, disrupt their blood sugar patterns in any direction.
That wouldn't be healthy.
But for most people out there who have reasonable blood glucose levels, it's kind of interesting
and kind of fun to play with these parameters in order to optimize what you want to do.
And sometimes that might change across the year with schedules.
Many people find great benefit in having flexibility over when they eat.
Regularity of eating equals regularity of
grellinsacretion equals regularity of activity of these
AGRP neurons, meaning you will be hungry at very regular intervals.
So that's something that you can work with. It's grounded in deep mechanism
of hormone and neural systems, and there's a lot of modern research to support
what I just said. So if MSH inhibits feeding, makes us want to eat less, and Grellen makes us want to
eat more, there's another hormone called CCK, Coli cysticinin, that is potent in reducing
our levels of hunger.
Now I learned about CCK back when I was an undergraduate, so well over 20 years ago, when it was first
discovered, and there was a lot of excitement about CCK at that point as a diet drug.
Anytime there's a molecule or a chemical discovered in the brain or body that can suppress
feeding, the diet industry just goes wild and think, this is going to be the thing that's
going to allow people to move from being obese, to losing all sorts of unhealthy weight, etc.
A similar phenomenon was observed with leptin.
Leptin is a hormone that's made by body fat that signals to the brain when there's a lot
of body fat and in animals, injections of leptin can make fat animals thin.
They lose a lot of adipose or fat. In humans, it didn't work out
that way. It just the studies were done and leptin was successful in treating a certain rare
form of diabetes, but it really wasn't very potent as an anti-obesity drug. Similarly, CCK has been
looked at as an obesity drug, something to reduce obesity, but it had some
pretty unhappy side effects, actually cause some pretty serious side effects.
Now that's as a drug. However, CCK, when released at normal levels by your gut, has a
powerful effect in suppressing appetite for a period of time. And there are healthy and direct ways to activate CCK.
Now CCK is in the GI tract, it's released from the GI tract, and its release is governed
by two things.
One is a subset of very specialized neurons that detect what's in the gut, the specific
contents of the gut.
And by certain elements of the mucosa, the mucous lining of the gut and the specific contents of the gut, and by certain elements of the
mucus, of the mucus lining of the gut and the gut microbiome.
So what's really interesting is that CCK is stimulated by fatty acids and particular
fatty acids that we'll talk about, amino acids and particular amino acids that we'll talk about, as well as by sugar.
Now let's put sugar on the shelf for a moment.
We're going to talk a lot about sugar because if CCK inhibits appetite and reduces feeding
and it can be triggered by fatty acids, amino acids, or sugars, then you might say,
well then eating a lot of sugar
should make us not want to eat more, but we all know that eating sugar makes us want
to eat far more.
That's the role of a lot of sugars, and that has to do with a separate mechanism we'll
talk about today.
So, which fatty acids in the gut stimulate the release of CCK?
It turns out it's the omega-3 fatty acids, the ones that come from
algae or krill or fish oil. I talked about this in the episode on nutrition and some of the things
related to the gut microbiome, but I'm going to revisit that now. Omega-3 fatty acids and conjugated
linoleic acid, CLA, either from food or from supplements, stimulate the release of CCK, which then reduces
or at least blunts appetite.
And I'm not talking about blunting appetite to anorexic levels where you don't want to
eat at all.
I'm talking about regulating appetite to the point where animals and people don't overconsume.
So it's keeping appetite at a healthy level.
The other thing that stimulates CCK that I mentioned are amino acids. So when
we eat, we have the ability to break down different macronutrients, carbohydrates, fats,
or proteins into sugars and glucose that then we can convert to ATP and all that stuff
from the Krebs cycle from high school. We're not going to go into that today. That's
for a future episode. But amino acids are one of the things
that we are eating for.
Amino acids both can be used as energy
through a process called gluconeogenesis
of converting proteins into energy.
Or those amino acids can be broken down
and then rebuilt into things like preparing muscle tissue
as well as other forms of cellar repair,
involved in all sorts of things related to protein synthesis.
What does this mean?
If we eat the proper amino acids at the proper levels,
if we ingest omega-3s and CLA's conjugated linoleic acids
at the proper levels or get them from supplements,
there is a blunting of appetite.
Appetite is kept clamped and we
don't become hyperfagic. We don't overeat. We tend to eat within healthy or normal ranges.
So this is very important because most people don't understand that when we're eating,
we are basically fat-foraging and amino acid-foraging. And there are several studies now have
shown that people and animals will essentially eat
until they feel they've consumed enough
omega-3s, omega-6s, CLAs, and certain amino acids.
In other words, even if it's not conscious,
we are eating until we trigger the activation of CCK.
Now there are other reasons why we shut down eating too.
Or literally the volume of food in our gut can be large and we can feel very
distended. That's the physical reason, obviously. There are other reasons. Maybe we
just have top-down control. We have knowledge that this is the end of the meal and
we stop because we have to go back to work or to a meeting or we tell ourselves that we've had enough. But at a subconscious level,
the gut is informing the brain,
via CCK and other mechanisms,
when we've ingested enough of what we need.
And these omega-3s and CLAs and certain amino acids
are vital for sending out that signal that we've had enough.
Now, which amino acids is actually really interesting?
We have essential amino acids
and we have non-essential amino acids.
Among the essential amino acids,
there's one in particular that can trigger
the release of CCK very potently,
and that's glutamine.
Glutamine is a very interesting amino acid.
First of all, it's been shown in a few studies
to play a role in bolstering the immune system.
It can increase the number of killer cells in the immune system.
It is consumed in supplement form.
People can take it a teaspoon of glutamine or some people take glutamine throughout the
day if they're really into it or for whatever reason they think they're battling off an infection
or something of that sort.
Glutamine can also of course be derived from foods.
You can just put into the
internet, put doing internet search and find out what foods are rich with glutamine. Some of the
ones that I'm aware of off the top of my head are like cottage cheese and things of that sort,
but other foods have glutamine as well. Once a threshold level of glutamine and other essential amino
acids are reached, once a threshold level of these alpha 3, excuse me omega 3 fatty acids
and CLA's are reached, CCK is released and it helps reduce the activity of those AGRP
neurons that promote feeding.
So as you can see, feeding is an interplay between brain and body and it's some of the micronutrients
and even the breakdown of particular nutrients that's putting the accelerator or the break
on the feeding process.
It's not just one thing. So from an actionable standpoint,
you, we should probably all be trying to get our omega-3 omega-6 ratios correct anyway,
because they are antidepressant. I talked about the peer-reviewed studies on that. They are healthy
for the gut microbiomeome and we should be seeking
sufficient glutamine. Now, whether or not you decide to supplement with glutamine or not
is up to you. One of the reasons why one might want to do that, and again, you should always
check with a doctor, especially if you have any predisposition to cancers or you have cancer,
many cancers and tumors like glutamine. So that's something to note.
But one reason why you might want to supplement with glutamine or consider eating foods that
are rich in glutamine isn't just to keep your appetite in healthy ranges, but as well,
glutamine can actually reduce sugar cravings.
So this is very interesting.
I have a friend, he's an absolute chocolate sweets addict.
He's a grown adult, but he eats candy and chocolate
as if he was like a 14 year old kid hanging out
at the local convenience store.
It's really incredible.
And he has probably a sugar addiction,
but he's very aware of this,
and he's managed to kick all other addictions.
So for whatever reason, it stimulates his brain and body
in the ways that make him want more, but he hates this.
It's actually quite frustrating for him and he's somebody who cares a lot about his health.
He took the approach that I know many other people have who know about this role of glutamine
of taking a teaspoon or a couple teaspoons of glutamine several times throughout the day
or any time he craves sugar.
And indeed, glutamine will reduce sugar cravings. Some people who are really
on the kind of ketogenic front will mix it with a little bit of half and half and down that,
and because I guess it makes it taste better, it's a little bit chalky. So glutamine has some very
interesting properties, but I think for most people that aren't suffering from adverse levels of craving,
making sure you're getting the right omega-3s that can come from a variety of craving. Making sure you're getting the right omega-3s, that can come from a variety of sources.
Check out the episode we did on nutrition if you want to learn more about that. And CLAs.
And making sure that you're getting enough glutamine is going to be important for making sure
that this CCK signal gets through. The one thing I do want to mention about glutamine, it's a
minor effect, but it alone can have a small increase, excuse
me, it alone can increase blood sugar.
It's not a huge increase in blood glucose, but because the gut takes proteins and breaks
them down into these amino acids and essentially looking for glutamine and things like it, other
essential amino acids as well, when you ingest glutamine or branch chain amino acids, there
is a small but real increase
in blood glucose.
And that's because they are essentially food.
And there I'm talking about the supplemental version.
So just know glutamine can increase blood sugar slightly, especially diabetics should know
that.
It can reduce sugar cravings.
And just know that what your gut is doing at a core level is it's forging
it's waiting and it's trying to assess levels of omega-3 fatty acids, conjugated linoleic
acid, and glutamine and other essential amino acids.
You are essentially trying to eat to get these nutrients, and then a signal can be deployed
up to your brain that you're not really interested in eating that much more.
Whenever preparing an episode for this podcast, I'm always faced with a particular challenge,
which is how many tools should I offer
that involve doing something new,
you know, a new behavior,
a new exercise, supplements,
something, things of that sort,
and how many should be related to not doing things,
avoiding things.
It's never really fun to talk about all the things
that we're supposed to avoid,
but some of them are so powerful
in light of the mechanisms of a given topic that I'd be remiss if I didn't mention them.
So now you understand how hormones and peptides like CCK and Grelan impact appetite.
There's one particular aspect of food that can powerfully impact CCK and I think most people,
I'm guessing 99.9% of people out there are not aware of this.
And it has to do with highly processed foods.
There's a lot of reasons why one would want to avoid highly processed foods.
In fact, if you're interested in that topic and the history of whole foods transitioning
to highly processed foods in this country, I highly recommend you listen to a YouTube
video by Dr. Robert Lustig.
He's a University of California, San Francisco. It's very easy to find. Put Stanford,
Robert Lustig. It was a talk hosted by Stanford. It gives a beautiful description of the history
of this and why the food industry started packing in additional sugars and salts and
turning foods into commodities. It's really fascinating. It has no conspiracy theory It's just all scientific facts. It's really a wonderful lecture as millions of views should be very easy to find
We can provide a link to that and we will
There's another reason to avoid highly processed foods however and that has to do with what's called a
Mulsifiers now many of you are familiar with the Mulsifiers though you don't know it. When you put detergent in the laundry that contains emulsifiers. The goal
of that detergent is to bring together fatty molecules with water molecules and
be able to dissociate them and break them up to get the stains out of clothes
and things of that sort. There are a lot of emulsifiers put into processed foods. And those emulsifiers
allow certain chemical reactions to occur that extends the shelf life of those foods. So it's
like candy bars and cereals and all sorts of things that are in processed foods. The worst of which
are the typical kind of pastries that you see at the convenience store, but this extends into
chips of various kinds and even some meats of various kinds,
they pack the stuff into meats.
They have names like soy lechethin and other things.
Why are emulsifiers bad?
Okay, there are a lot of reasons why they're bad,
but the reason why they're bad for the mechanisms
that we've been talking about today
is that when you ingest those foods,
you're bringing those emulsifiers into your gut.
And those emulsifiers strip away the
mucosal lining of the gut and they actually cause the neurons that innervate the gut that
extend those little processes we call axons into the gut to retract deeper into the gut.
And as a consequence, you're ingesting a bunch of food and the signals like CCK never get
deployed.
The signals that actually shut down hunger
are never actually triggered. And so as a consequence, you want to eat far more of these
highly processed foods. In addition, if you then go from eating a highly processed food to non-highly
processed foods, you're not able to measure the amounts of amino acid sugars and fatty acids in
those foods as accurately. You've actually done structural damage at a micro level, but structural damage, excuse
me, to the mecosolining of the gut.
Now this can all be repaired if you stay away from highly processed foods for some period
of time, but the negative effects of these emulsifiers are quite real.
So to make it really clean and simple, a molsifiers from highly processed foods are limiting your
gut's ability to detect what's in the foods you eat and therefore to deploy the satiety
signals, the signals that shut down hunger.
In addition to that, there's a parallel mechanism at play that I talked about in a previous
episode, but I'll remind you again that you have neurons in your gut that are sensing sugar and are sending a subconscious signal up to the
brain via the vagus nerve.
And those neurons trigger the release of dopamine, which makes you crave more of that food.
So now you've got parallel signals making you want to eat more sugar, making you unaware
of how much sugar you've eaten, and that it is disrupting the inputs to the nervous system
that signal to the rest of your
brain and body that you've obtained enough fatty acids and you've obtained enough amino
acids.
So these highly processed foods are really terrible.
And I'm not out here to say never enjoy a processed food of any kind.
I'd be a hypocrite because I do eat processed foods from time to time, although the ones that
I tend to eat, I try and make of the healthier variety. But eating whole foods has tremendous value and eating highly processed food has tremendous
negative impact on the gut and on the gut brain axis.
And so recently, there was a paper that came out in cell, cell press journal.
It's kind of the apex of cell journals, which is phenomenal.
This paper showed that ingesting highly processed food
leads to more intake of not just highly processed foods,
but other types of food.
In general, there was kind of an overeating compensation
generally across foods for people
that consume these highly processed foods.
And there are a lot of other reasons
to avoid highly processed foods.
So again, I don't like to focus too much on the do-nots.
I like to army with tools to do, but I think this visual of certain foods and these
emulsifiers actually stripping away some of the critical lining of your gut and disrupting
the hormone signaling to the brain controlling feeding is important enough and cryptic
enough, meaning it hasn't been talked about.
It works at a subconscious level and that it's important that people
are aware of it so they can make decisions about what they do want to eat or not want to
eat for themselves.
Before moving on, I just want to say one more thing about highly processed foods.
There was an absolutely beautiful study done by my colleague, Chris Garner at Stanford,
exploring whether or not certain diets were better than the others.
They looked at vegan, vegetarian, omnivore.
I don't know if they looked at all meat or not,
but they looked at the different forms of diets,
intermittent fasting, et cetera.
And they essentially found that whichever diet
people adhered to, whichever one they followed,
was equivalent to the others provided that they followed it.
They lost the equivalent amount of weight.
There really wasn't a strong effect of the food type or the pattern of eating, etc.
However, in a study like that, adherence is very high because people are part of a study.
And for many people, the ability to adhere to a certain eating plan is one of the most,
if not the most, powerful determinants of whether or not a given diet, meaning nutritional
plan, works.
Now, this thing about highly processed foods, however, is really diabolical because it truly says,
and I think the recent data in cell metabolism and other journals really proves that a calorie is not a calorie.
That's absolutely absurd because of these emulsifiers and the content of these highly processed foods.
In fact, the data in humans points to this.
So what they did is they took inpatient adults, so they had total control over their food intake,
and they received either ultra-processed or unprocessed diets for 14 days in a short study.
The diets were matched for calories, sugar, fat, fiber, and macronutrients.
So everything else was matched. Just processed or
non-processed is the major variable. And basically what they found is that the people who were eating the
processed food diet happened to eat much more. This was after this period of putting them on either
diet and clamping for all other variables. Then they would eat much more and the body weight changes were much more.
And those body weight changes were such that they couldn't be accounted for by just increased
calories.
So, the bottom line is that highly processed foods are just bad for you.
They increase weight gain.
They disrupt the lining of your gut in a way that disrupts things like CCK and proper
satiety signals.
And they contain a bunch of things in particular sugars,
but other things as well, that disrupt not just the hormonal
systems, but also the neural systems that control the desire
to eat after the diet is done.
So there's just so many reasons why these highly processed
foods are terrible.
And they can explain a lot of the ill health effects
that we've seen in the last 50 years,
not just in the United States, but all over the world, the enormous increase in diabetes, juvenile
diabetes.
It's just remarkable how far down the path of bad we've gone, and it's clear, it's almost
a smoking gun, what the cause of this is.
If you'd like to learn more about that, please refer to the Lustig lecture.
He also spells out why non-process foods
is far more economical in terms of just
at the level the household or individual,
as well as at the societal level.
Really interesting stuff.
I highly recommend you check it out.
So now let's move on to some other hormones
that regulate hunger and satiety.
In particular, insulin.
Now, you've probably heard of insulin before.
Insulin is the thing that's lacking in type 1 diabetics.
That's why they have to inject insulin whenever they eat.
The reason they have to do that is because when they eat,
their foods are broken down into glucose.
And in order to shuttle glucose to the appropriate tissues in the body
and also to keep glucose levels in check, you need insulin.
So, the simplest way to think about insulin and glucose is that when you eat, that food
is broken down into sugars.
That's true whether or not it's fats or it's sugars or eventually if it's proteins.
They are oxidized into fuels, as we say.
And those fuels can be used as the name fuel implies into energy.
They're eventually made into ATP.
There's a bunch of biochemical steps that we're not going to go into today, but that's
essentially out works.
You break down food into glucose.
Now, if you're ketogenic, we'll talk about that in a little bit, but in general, you eat,
food is turned into glucose.
Your blood sugar needs to be kept in a particular range.
Hypoglycemic means too low. hyperglycemic means too high, and what they call u-glycemic,
EU-glycemic, is the healthy range.
Now, what those healthy ranges are, in general, the healthy range, the u-glycemic range is about
70 to 100 nanograms per deciliter, but
most of you aren't walking around with a glucose monitor.
Some of you are, but most of you are not.
The more important question for us to address right now is why is it important that glucose
be kept at a particular level?
Once you understand that, keeping glucose in check starts to have a rationale behind it
and the ways to do that start to make a lot more sense.
So the reason is, if glucose levels get too high because of the way that our cells in particular neurons interact with glucose,
high levels of glucose can damage neurons. It can actually kill them. You can start getting what are called peripheral, excuse me, neuropathies. One of the symptoms of some forms of diabetes is that
people start losing the sensation of touch in their fingers or their hands or their feet,
and they can start going blind. There's diabetic retinopathies. So it's very important that insulin
manage your glucose levels. Now, there's also type two diabetes
where there's insulin secreted from the pancreas,
but people are insulin insensitive.
There's a disruption in the receptors
and insulin insensitivity isn't quite the same
as having no insulin at all,
but it parallels some of the same mechanisms.
Now, type one diabetes is often picked up because someone has a sudden weight loss because they're not processing blood sugar
the same way they were before. Type two diabetes is often, although not always associated
with being overweight and with obesity. Both of them are challenging conditions. Type
two diabetes almost always can be managed by managing one's weight.
And of course, there are prescription drugs and supplements that can help manage those.
We're going to talk about all of that.
But for most people that don't have diabetes, the important thing is to manage glucose,
to keep it in that euglycemic range.
And there are a number of different ways to do that.
Some of them are behavioral, some of them
are diet based, and some of them are based on supplements or prescription drugs. So let's talk
about those now. So if you eat, and in particular, if you eat carbohydrates, blood glucose goes up.
If you eat fats, blood glucose goes up to a far less degree, and if you eat proteins,
depending on the protein, it'll eventually be broken down for fuel or assembled into amino acid chains for protein synthesis and repair of other tissues and bodily functions.
But glucose goes up and then is kept in range.
When you are hungry, you secrete a different hormone and that's called glucagon. And glucagon's main role is to pull stores of energy out of the liver and
the muscles and once those are depleted, you'll eventually tap into body fat.
Okay, so and this is for people that have a typical blood glucose range. So that 70 to 100
uGlycemic range. So the two kind of push and pull systems
that we're gonna think about now to keep this simple
is that you have the insulin system managing glucose
and you've got the glucagon system pulling energy
out of your liver and muscles for immediate fuel
and eventually you'll pull fuel out of body fat
if you've been active for a very long time
and all your glycogen
stores are depleted or close to depleted. So what does this all mean? There's a lot of important
biochemistry and a lot of important cellular processes involved in whether or not you're
anabolic or catabolic, whether or not you're breaking things down or building things up.
Let's talk about feeding in a simpler way, however. And let's weave the tools to manage blood glucose to keep it in check as we do that.
So let's say you had a meal and that meal consisted of rice, a carbohydrate, some meat or fish,
let's say a piece of salmon, and some vegetable, some fibers vegetable, like asparagus or cabbage
or something like that.
If you were to eat all of that at once, you take a bite of one, a bite of the other,
you have mix it up, one of these, it all ends up in the same place kind of people, mix
it all up.
Then you'll experience an increase in insulin and increase in blood glucose that's moderately
fast.
It's going to increase pretty quickly.
What's remarkable is that the order
that you consume each macronutrient
has a pretty profound influence on the rate of insulin
and glucose secretion into the blood
and how quickly those levels rise.
So if you will make it really simple,
if you were to eat the rice first,
your glucose would rise in a sharp spike,
especially if it doesn't contain you were to eat the rice first, your glucose would rise in a sharp spike, especially if
it doesn't contain any fats to slow the absorption.
Now that might be good if you're very hungry and you want to get an increase in glucose.
In fact, this is the reason why you're often served bread before meals because it's
and sometimes it's bread and butter, but or chips before meals or appetizers are designed
to get your blood glucose going up high,
because big, steep increases in blood glucose tend to promote the desire to consume more glucose.
And this also relates to the dopamine system in the way that something tasty in the mouth,
and sugar in the gut, and fats, and sugars in the mouth,
trigger the activation of a lot of systems in the brain and body to consume more of whatever you have or whatever is available to you.
So the basic idea is that eating carbohydrates and or fats early in a meal will give a steep
rise in blood glucose.
However, if you were to eat the fibrous thing first, so a lot of chewing, but not a big
rise in blood glucose because in general, there's unless it's late in with sugar or something, we're just talking about
some vegetable, fibers of vegetable, that will actually blunt the release of glucose
until you eat the fish and the rice. But believe it or not, it will actually blunt the
glucose increase that the rice would cause. Now, I'm not talking about neurotically eating
each macronutrient separately in sequence. I'm just trying to
give you a picture of what's happening ordinarily. So what this means is if you
feel a lot of food related anxiety or you feel you're one of these people that
you can kind of sense like your blood sugar increasing very quickly. A lot of
people can sense this. Some people can't. Has a lot to do with how well they
manage their blood sugar as well as some of the psychological factors. And yes,
they're family and historical reasons where you know, I've got friends who had a lot of
siblings. And when they sit down to eat, they have to really suppress the desire to not,
you know, beat up everyone else at the table and take all the food. It's sort of like not,
it's hard for them to understand that there's plenty to go around because of their upbringing.
So there are psychological top down effects.
A lot of the psychology around food is geared towards getting people to be relaxed when they
eat and these sorts of things.
But these blood sugar effects are real just cellar and basic biochemistry of how the body
manages sugars ingested into the blood.
So what does this all mean?
It means that if you want a steep increase in glucose,
you are very, very hungry, then you should eat
the carbohydrate, late in food first,
or you should eat a bunch of macronutrients combined.
That would be like the hamburger or the sandwich,
the bread, whatever's in that sandwich altogether.
Usually that's protein and vegetables as well.
If you want to have a kind of more modest increasing glucose or you want to blunt the increasing glucose, then have
the at least some of the fibrous thing first and then the protein and then the carbohydrate.
You will notice that your blood glucose will rise more steadily and that you'll achieve
satiety earlier in the meal or at
least you won't get this huge peak. It's sort of the Thanksgiving meal effect.
Some of you are international so if you don't celebrate Thanksgiving is a time of
a year where used to be the one time of year or two times a year where Americans
would give themselves permission to eat enormous meals. Now that seems to happen
a lot more often but there is this effect of your full and yet you're hungry for more.
That's because your blood glucose has gone through the roof and it's triggered a number
of other mechanisms.
There's also usually a lot of alcohol consumption and alcohol itself because it's a sugar
will increase blood glucose very, very sharply.
It depends on the alcohol.
Some alcohols have more sugar than others, but basically what you're trying to avoid are steep increases in blood sugar.
And the order that you eat foods has an enormous impact on that.
The other thing that has an enormous impact on how long and shallow or how steep that curve
of glucose is depends on whether or not you recently were moving or are moving or start
moving after you eat.
So it turns out that your blood glucose levels
can be modulated very, very powerfully by movement.
If you did any kind of intense exercise
or even just walking or jogging or cycling,
anything before you eat,
your blood glucose levels will be damp and somewhat.
And that has to do with the release of something called,
some people call it glut4, which sounds like glutton. Other people call it glute4. These are things
that are involved in shuddling glucose to particular cells in the body, namely toward muscle
and glycogen stores and away from body fat stores. It has to do a sequestering of glucose
from the blood. The point is that if you're somebody who struggles with blood sugar regulation,
in addition to getting your body weight in a healthy range, doing all the other sorts of things that you should
be doing, the key thing is to try and get some movement, some time, a circa meal.
Now, very few people can actually eat and walk at the same time, although I do it all the
time, not because I'm trying to regulate my blood sugar, but just because I tend to be busy,
I eat and drive, I'm busy, I'm not giving this podcast or sleeping, I'm trying to regulate my blood sugar, but just because I tend to be busy, I eat and drive, I eat and drive, I'm busy,
I'm busy if I'm not giving this podcast
or sleeping, I'm eating,
but it's up to the early part of the day when I fast.
But the bottom line here is that if you, for instance,
take a 30-minute walk after a meal,
your blood glucose will be blunted in ways
that are beneficial.
If you have exercise in the recent hours
before a meal, that can be beneficial.
The order that you consume foods is beneficial.
There are a few things that you can consume that can also adjust blood glucose levels.
Let's talk about those, but I thought it was important to really tamp down that it's
not just what you eat.
We talked about that before, but also the order that you eat those things, believe it or
not, whether or not you combine macronutrients, carbohydrates, proteins, and fats, and fiber vegetables.
And whether or not you've moved recently, the higher intensity of the movement, the greater
the glute for increase, and the more that the blood glucose will be blunted, and you'll
shuttle more of that to glycogen and muscle stores.
And even just moving after a meal, even just a calm, easy walk, can really adjust the
ways in which blood sugar regulated for the better.
I don't want to perseverate on this process foods hidden sugars thing too much, but understanding
now a little bit about how insulin and glucose work, you can probably imagine why hidden sugars
are such an attractive thing from the standpoint of process food manufacturers
because if they can put sugar in that you can't even taste, that sugar is going to amplify the amount of glucose.
It's going to increase the rate of glucose increases into your bloodstream and it's going to promote more feeding.
So in that case, you're really being tricked. It's not that you're actually reaching for the additional appetizer and your blood glucose
is going up.
The food that you ate is actually increasing your appetite as you eat it.
It's a positive feedback loop.
So don't want to demonize those anymore than I already have, but you should be aware
that these things are happening at the level of your bloodstream and brain.
The other thing I'd like to address for a moment is this notion of stable blood
sugar versus labile blood sugar or unstable blood sugar. Some people just have stable blood
sugar. They can go long periods of time without eating and feel fine. Other people get really
shaky, really jittery, and or when they do eat, they feel really keyed up. Sometimes they'll
even sweat. Sometimes their vision will go blurry.
And some of that can actually be
because they become hyperglycemic.
And those effects that you experience
when you are hyperglycemic are the early warning signs
of the kinds of things that damage neurons
and leads to the really terrible stuff
they talked about before, like peripheral neuropathy.
Now, it takes some time for those things to occur, those neuropathies to occur,
but whether or not your blood sugar is all over the place or whether or not stable,
can be impacted by a number of things.
One of those things is exercise.
So, these days there's a lot of interest in what they call zone two cardio,
which is that kind of steady state cardio where you can just nasal breathe,
even at pretty high output
Where you could maybe have a conversation although I'm such a huge proponent of nasal breathing during exercise most forms of exercise Especially zone two cardio that you probably shouldn't be talking while you're doing that cardio unless it's absolutely essential
but periods of zone two cardio
That last anywhere from 30 minutes to an hour
or sometimes more for your endurance athletes
can create positive effects on blood sugar regulation
such that you, people can sit down and enjoy whatever it is,
the hot fudge sunday or whatever the high sugar content food is.
And blood glucose management is so good,
your insulin sensitivity is so good, your insulin sensitivity
is so high, which is a good thing, that you can manage that blood glucose to the point
where it doesn't really make you shaky, it doesn't disrupt you, and to say nothing of
the weight-related issues or the adipose fat gain, et cetera. That's a separate issue because people vary there. But basically doing zone two cardio for 30 to 60 minutes, three to four times a week,
makes your blood sugar really stable. And that's an attractive thing for a variety of reasons.
On the flip side, high intensity interval training or resistance training,
aka weight training, are very good at stimulating the various molecules that promote repackaging
of glycogen.
So sprints, heavy weight lifting, circuit type weight lifting provided there's some reasonable
degree of resistance.
Those are going to trigger all sorts of mechanisms that are going to encourage the body to shuttle
glucose back into glycogen, converted into glycogen into muscle tissue, restock, deliver, etc.
Depleting one's glycogen actually takes some time.
If you do a couple sets of tricep extensions and some crunches, you're not depleting your
glycogen.
Glycogen depleting workouts are very high intensity.
Generally they're less than an hour or so, but those are the sort that are going to lead
to big increases in the kinds of enzymes and metabolic pathways that are going to repat glycogen and shuttle most things towards
restorge of foods, not into adipose tissue, not into fat, but taking glucose and making
it into fuels that you can access later for more of that high intensity activity.
And I should mention that one of the advantages of high intensity interval training or weightlifting
of various kinds is that it also causes long standing increases in basal metabolic rate.
I don't want to go too far down this path because we're going to do an entire month on human
performance and athletic performance.
But it's not just the increases in muscle that increase metabolism because muscle burns more
energy than other types of tissues, except your brain, which truly burns the most energy.
And is the main reason why your basal metabolic rate is what it is.
Well high intensity training, so it could be sprints, it could be a high intensity interval
training of different kinds, cons could be weight training. Also has an effect of increasing thermogenesis even long after you've completed the exercise.
So there's a long tail.
There's a kind of post-exercise metabolic effect that's also beneficial.
So it's not an either or.
It's really that high-intensity interval training and resistance training and things of that
sort are very good for one reason.
And the zone two cardio is very good for other reasons,
and now you can see why it's just a healthy thing,
and why most people should probably be doing exercise
most days of the week, if not every day of the week.
If your goal is to manage blood glucose,
and your goal is to manage some of the metabolic factors
that control repackaging of glycogen,
and encouraging excess glucose
to not get diverted into body fat stores.
We haven't talked a lot about lipids today, that's because most of today's discussion
is about hormones and insulin is the dominant hormone in terms of mobilizing and managing
glucose in the body, at least for most people.
But fats are very important and there's just a little anecdote about fats
that I think will be useful in thinking about
why you want to manage what they call the LDL or HDL ratios.
This is deserving an entire episode,
many perhaps even several episodes,
but some of you may be familiar with LDLs and HDLs,
some of you may not.
The LDL is low-density lipoprotein. This is the one that you don't want it to be too high.
Costello is dreaming. He's barking. He doesn't, he loves all forms of cholesterol, but that's just Costello dreaming.
So LDLs are the ones that you want to keep low. You don't want those to go excessively high.
HDLs, the high-density lipoproteins are the ones that are the so-called healthy lipoproteins.
That's all finding good, but you might ask yourself,
what are they doing?
What is the actual role of these things?
And why would you want healthy levels of HDL
and not too much LDL?
Well, one of the reasons is that fats don't like water, right?
They are hydrophobic. And yet you need to move fats in't like water, right? They are hydrophobic.
And yet you need to move fats in your bloodstream,
all tissues in your body need fats, they need cholesterol,
they're last episode we talked about cholesterol
as a precursor to the sex steroid hormones, estrogen
and testosterone and other hormones as well.
Well, HDL and LDL actually coat fats
that to allow them to be transported through the bloodstream.
They do a number of other things as well, but HDL is a key component of the delivery system
that brings those fats to the liver, ovaries, testes, and adrenals.
In other words, having adequate levels of HDL is good because it allows fats to be delivered to the tissues that manufacture testosterone, estrogen, cortisol in healthy levels, and deliver.
So this is why when LDLs are too high, what's happening is you're not getting fats to the
correct tissues and you can get build up of fats like fatty liver disease and some of these
things can happen.
High sugar content can even lead to some of these fatty liver conditions that starting
to happen is actually the first time in human history perhaps that we're aware of.
Anyway, that we're starting to see liver conditions that normally were associated only
with severe alcoholism starting to come from sugar content.
So what does this mean?
This means keep your LDL and HDL ratios proper.
You want those HDLs in order to deliver fatty molecules to the very tissues that use cholesterol in order of
manufacture hormones. So how do you keep LDLs and HDLs in their proper ratios? Well,
a lot of people don't realize this, but the debate about dietary cholesterol and its relationship
to LDL and HDL ratios is a
barbed wire debate.
I don't want to get into it right now.
There are still a lot of open questions as to how much dietary cholesterol impacts LDL
and HDL ratios.
I don't want to get into that now.
I'm not taking a stance either way.
What is very clear is that having highly elevated glucose, consuming too much
sugar or not managing glucose in your body through some of the mechanisms that we've been
talking about up until now, can also negatively impact LDL HDL ratios. So managing glucose
goes way beyond just managing blood sugar and making sure that you don't lay down too
much body fat, making sure your metabolism stays high, making sure you're not getting jittery at meals.
It also has to do with making sure that you're creating enough of the molecules HDL and
not too many of the molecules LDL that are going to disrupt the delivery of things to the
organs of your body that allow you to make healthy levels of testosterone estrogen and
so forth.
If that wasn't clear, let me make this ultra simple.
You want healthy levels of HDL and you want low levels of LDL because if you have ovaries,
it will allow the fats that need to get to the ovary to produce estrogen to get there.
And if you have testes, it will allow the fats and the cholesterol molecules that you need
in order to manufacture testosterone to get to the testes, as well in order to have proper
adrenal function and proper liver function, you want HDL and LDL in the healthy, correct
levels.
So now we've talked a lot about behavioral tools and the underlying biological mechanisms
that justify those
tools in particular circumstances.
Now I'd like to turn to supplements and prescription drugs that regulate the hormone systems, controlling
feeding and satiety.
There are a huge number of these, some have more powerful effects than others.
There are two that I want to describe because they've been getting a lot of attention recently.
First of all, there's a prescription drug,
Metformin, which was developed as a treatment for diabetes.
And it works potently to reduce blood glucose.
It has dramatic effects in lowering blood glucose.
Metformin involves changes to mitochondrial action
in the liver.
That's its main way of depleting or reducing blood glucose.
And it does so through the so-called AMPK pathway.
And it increases insulin sensitivity overall.
Metformin is a powerful drug.
In fact, I'm surprised that so many people have sought it out,
given that most of the people that I'm aware of
that sought it out are not diabetic.
I think for diabetics, it seems to be a useful drug.
For non-diabetics, it can also, of course,
lower blood glucose.
It also has the potential to make people hypoglycemic,
genuinely hypoglycemic.
So you really need to approach metformin with caution.
I get a little concern when I hear about people blasting metformin simply because
fasted states or low blood sugar states are healthy.
Doing that pharmacologically can have long standing effects. You really want to approach that with caution.
Now, there's a comparable drug. It really should be called a drug, but it's non-prescription that's also in fairly prominent
use out there called Berberine.
B-E-R-B-E-R-I-N-E.
Berberine.
Correct.
So, Berberine is a really interesting compound.
It's actions very much mimic metformin.
So let's talk about Berberine for a second.
Berberine actually comes from various plants and tree bark.
It is sold in supplement stores, it's sold online,
it is as far as I know, unregulated.
It is powerful.
If you're going to experiment with burberine,
you definitely want to talk to your doctor
and you want to approach it with caution.
It also works to activate the so-called AMPK pathway.
AMPK, by the way, stands for Adenosine Monofosphate Activated Protein Kines, AMPK.
And it inhibits a protein tyrosine phosphase, 1B pathway.
I think that's enough nomenclature.
It activates a certain pathway that's associated with fasting and low blood glucose.
The effects of burberine are as far as I can tell when looking at the
literature are very similar if not identical to metformin. Now, the number of studies out
there on this are many. So I'm just going to review a few of them and their major effects.
As always, I invite you to check out examine.com. It's a wonderful website where you can put in any supplement or compound or biological
goal for that matter.
And it will list out the various effects in the human effect matrix.
So studies on humans, if they're available.
And it will tell you whether or not they're strong effects or weak effects or modest effects.
And it will point to the specific subject population, a wonderful resource.
So Burberry not surprisingly has very strong effects
in lowering blood glucose.
There are four studies on this.
In fact, they say that burberry is one of the more,
if not the most effective supplements
for lowering blood glucose.
It talks about dosages there,
although I'll just mention that I've tried burberry
and the dosages that are typical on the bottle
of most supplements is much higher
than I needed.
When I took burbring, two things happened.
First of all, I got a pretty splitting headache.
It gave me pretty vicious headache.
For me, it was a no almost immediately.
The other thing is I became so hypoglycemic that in order to get my blood sugar back up,
I think I ate something like 10 donuts
and I didn't feel like I had ingested all that much sugar.
It was really kind of weird.
I was hyper-phagic for sugar.
I was craving sugar, craving sugar,
and I was very thirsty as well.
And so I don't want to promote any bad behavior,
but I know that certain people use this
when they've overeat in sugars,
or they're doing their cheat days,
something that I'm personally just not a fan of, and they want to keep their
blood sugar in check or they know they're going to consume a huge meal.
They'll take burberry and to keep blood glucose clamped.
And it does do that.
It has very strong effects, three peer reviewed studies on HBA1C levels.
HBA1C is something that can be measured in a blood test that is sort of an average readout
of your blood sugar levels over the previous two or three months, sometimes shorter period,
but that's mostly what HBA A1C is about.
So it radically decreases your blood sugar levels.
It actually lowers cholesterol.
It acts remember on the liver and the liver is involved in cholesterol metabolism.
Remember, it's both sugars, blood glucose, and dietary fats, perhaps, it's still heavily
debated in terms of how your total cholesterol, HDL and LDL are regulated.
It seems to lower total cholesterol and it seems like it lowers HDL and LDL in parallel.
So that's interesting.
One study showed a minor increase in HDL, the so-called good cholesterol, insulin levels
drop, not surprising.
Another study showed a slight decrease in LDL, though it seemed to be kind of minor.
Here's the kind of interesting one, just help you remember Burberryin as if the fact that
it comes from tree bark isn't, you know, trigger enough to remember it.
Direct contact of burberry on canker sores seems to eliminate canker sores very quickly,
which is kind of cool.
I've been at canker sores in a few years, but when I dig down there, extremely painful.
Don't like those, so that's kind of interesting, and there's some study references there.
I find it amazing that these compounds exist.
You've got this prescription drug metformin, and then you've got burberry in this stuff from tree bark, and they have effects
that are essentially equivalent to one another.
So again, I'm not promoting their use,
or even their exploration,
but those compounds do exist.
They're out there, and check out examine.com,
if you'd like to learn more.
Certainly do your reading, do your homework
before you start just popping this stuff.
And if you have hypoglycemia or hyperglycemia B,
especially careful, and also do understand
that dosages and dose requirements vary.
So if you do go down this path,
really approach things carefully.
Always start with the lowest amount that you could get away with.
For me, the headache thing just made it a no go.
I do keep
a bottle of it in full disclosure in the odd chance that I feel like eating a ton of donuts.
It's not so much about not ingesting the calories. It's just that I don't like the feeling
of being hyperglycemic, the blurry vision, just feeling lousy. I do love donuts.
Other things that impact blood glucose in supplement form chromium has been shown in
29 studies to have a minor.
I want to emphasize a minor effect on reducing blood glucose, things like alkaline teen, something
we've talked about here on the podcast before, in terms of its relationship to power output
in ATP production for both aerobic and anaerobic exercise as well as sperm quality and egg quality.
We talked about that long ago. Things like panache, ginseng can have positive effects on,
I should say, can have effects of reducing blood glucose slightly. I don't want to give
valence to or judgment to whether or not it's positive or negative. Here's something
that's interesting that you should know about caffeine has very
reliably been shown to increase blood glucose just a little bit. Okay? So I always
thought that caffeine would drop blood glucose, but it actually can increase blood glucose.
Just slightly, things like magnesium. I've talked about about magnesium as a tool for enhancing the passage
into sleep, in particular magnesium 3 and 8
and by glycinate.
Magnesium can also have a modest reduction in blood glucose.
You're starting to get the impression
everything reduces blood glucose,
but that's certainly not the case.
And then a couple of episodes ago,
when we were discussing nutrition,
we talked about artificial sweeteners, sucralose,
aspartame, neutrosuite. episodes ago when we were discussing nutrition, we talked about artificial sweeteners, sucralose,
aspartame, neuter sweet.
Some of those are generic names, some of those might be brand names, and how they have negative
effects on the gut microbiome, and that's supported by a number of studies.
There's one artificial sweetener, it's stevia, STEVIA, which seems to lower blood glucose just slightly. And I still can't find data on whether or not stevia impacts the gut microbiome in either
direction.
Many of the things that I consume do have small amounts of stevia in them, so I'd love
to know if anyone out there is aware of quality peer-reviewed research as to whether or not
stevia impacts the gut microbiome similarly or differently from other artificial sweet
nerves. Please let me know. Please send me the references. I'd really appreciate it. You
can put in the comment section on YouTube or elsewhere. Comment section on YouTube would
be the best place. So stevia seems to lower blood glucose a little bit, which makes it
kind of an attractive artificial sweetener if one is going to use artificial sweeteners.
But remember, sweet taste itself stimulates the desire to eat, which will increase more
blood glucose.
So I'm guessing that they probably cancel each other out.
So you have to think logically about these things.
Vitamin B3.
So some of the B vitamins do indeed stimulate appetite by triggering increases in blood
glucose.
Vitamin B3 in particular.
I don't know if B6 does.
Things like zinc seem to lower blood glucose, vitamin B3 in particular. I don't know if B6 does things like zinc
seem to lower blood glucose.
And then there have been an enormous number of other things
that have been tested for the roles in blood glucose,
apple cider vinegar, anything acidic.
This is well known now that any kind of acidity,
so it could be lemon juice or lime juice
or apple cider vinegar lowers blood glucose slightly.
Some of those can also have other effects that we're not talking about today.
So, that's kind of interesting because there's a movement now towards creating sort of people
talk about becoming more alkaline.
You know, and these hate to break it to you, but you don't really want your body to be
to alkaline.
You want to stay in the right pH or else you start, there are conditions that make you more alkaline.
You don't want to be too acidic or too alkaline.
If you see a beverage or something that purports that
ingesting that beverage is going to make you more alkaline,
that is absolutely false.
No evidence for that is impossible,
biochemically, it's just marketing.
But nonetheless, ingesting foods that are acidic
can make some slight adjustments to the pH of the gut
in ways that can slow or alter the absorption of foods
and can blunt blood glucose.
You can try this sometime if you want.
If ever you're feeling kind of over sugared out,
like you ate something with too much sugar,
you can drink a small amount of lemon juice, mixed water or lime juice and you'll notice that it will
blunt that kind of hyperglycemic effect just a little bit. Again, you don't
want to use this as a medical tool but the effect is fairly potent. And then
then excuse me. And then there are a number of other things like capsaicin and hot
chili peppers that will lower blood glucose. The list goes on and on.
The most powerful one is absolutely burberry and metformin, but that's really heavy caliber
stuff.
The other ones I mentioned have more minor effects.
I do want to mention, because I'm sure some of you out there are curious about the ketogenic
diet.
I'm going to do an entire episode about ketosis and the brain and the body, but the ketogenic
diet has been shown in 22 studies to have a notable decrease on blood glucose, and that is not
surprising because the essence of the ketogenic diet is that you're consuming very little or zero
of the foods that promote big spikes in insulin and glucose.
If you consume enough protein, some of that protein can be converted into glucose, of course,
through gluconeogenesis.
But the ketogenic diet has very strong support for its role in regulating blood sugar, which
is glucose.
But the specific effects of the ketogenic diet And one particular effect that I'll address later,
but I'll mention now, which is the ability
of the ketogenic diet to adjust thyroid hormone levels
in ways that make it such that if you return
to eating carbohydrates after being in ketosis for too long,
you don't manage thyroid and carbohydrates as well.
That has been shown as well.
So we're gonna dive deep into ketosis in a future episode.
So for you, ketones does out there.
Don't worry, I certainly have nothing
against ketogenic diet.
I actually don't have anything for
against any particular nutrition plan.
I know what works for me,
at least at this stage of my life,
and I'll update it if I need to.
I'm simply trying to get you as much information
as I possibly can so that you can navigate
through that landscape in a way that's in keeping with your particular goals.
So now you understand a lot about blood sugar
and how it's managed and the ways that you can manage it
better depending on your particular needs.
This is also a good opportunity for us to look back
at some of the medical literature
because it really points to just how far we've come in terms
of understanding these important mechanisms.
And it points us in the direction of some actionable protocols.
So diabetes, which is these huge increases in blood glucose because there's no insulin,
was known about as early as 1500 BC, which is just incredible.
And the way physicians then understood
that certain people had high blood glucose
without actually knowing what blood glucose was,
is that they would take the urine of particular patients
and they'd find that ants preferably moved toward
and consumed the urine of certain patients and not others. And they
understood that there was something in that urine that was correlated with the
sun weight loss and some of the other probably very unfortunate health
symptoms that these people were experiencing. So they knew that there was
something in blood and urine. But you might not be asking yourself, wait, that's urine.
But as I tell every kid that I meet, two things,
I tell a kid, your brain is here,
I make them point to their head,
and then I tell them, do you know what?
Do you know that your urine is actually filtered blood?
And they usually go, I get parental permission
to do this first, but most adults don't realize
that your urine is actually just filtered blood.
And that's why if you see blood in your urine, that's a problem. You want to filter the blood,
but urine is filtered blood. Now this business of measuring blood sugar from the urine has been
something that lasted way beyond these early stages of 1500 BC. Turns out that
as late as 1674 physicians at Oxford University were figuring out who had pathologically high
levels of blood glucose by analyzing their urine. And again, they were measuring the sweetness
of their urine, but this is medical fact,
they would do this by taking urine samples from different patients and tasting them. And they
developed an intuitive sense of what excessively sweet urine was relative to the other
urins that they had tasted. So for those of you that are in the medical profession or those of
you that are seeking out the medical profession, do understand this is not done anymore. And
you can also just reflect on how far we've come in terms of the medical profession itself
in our ability to measure things from the blood and measure things from urine without
having to ask ants, which urine is sweeter, or ask oneself, which urine is sweeter. So indeed, we are making progress as a species.
Before we close out today, I want to talk about one more tool
that many of you will probably find useful.
I certainly have.
I'm a big consumer of caffeine,
although I don't consume a ton of it.
I consume it very consistently.
So I'm big on consuming mate,
which is a strong caffeinated
tea, and I generally do that early in the day. Although I do delay about two hours after
I wake up, for reasons I've talked about in previous episode to maintain that nice arc
of alertness and focus. I do drink black coffee as well, mushroom coffee as well. I love that stuff.
But mate, also called yerba mate, is an interesting compound because
unlike coffee, it has been shown to increase something called glucagon-like peptide, GLP1,
and increased leptin levels. Now, we didn't talk a lot about glucagon today. Glucagon is really
elevated in the fasting state. I mentioned that it's sort of the opposite of insulin in kind of
rough terms, that's one way to think about it.
But GLP1 or Glucogon-like peptide 1 is increased by ingesting mate and it acts as a pretty nice
appetite suppress.
Now, I'm not trying to suppress my appetite.
I like to eat, as I mentioned before, but it works really well to stimulate the brain
and to give you a level of alertness and to do a lot of the things that coffee does.
It also contains electrolytes.
So, we, meaning our neurons and our brain, run on a variety of factors, electrical activity
and chemical transmission, et cetera, but they require adequate levels of sodium, potassium,
and magnesium,
she, if you were to learn the biology,
or the physiology of the action potential,
the firing of a neuron,
something we teach every first year neuroscience student,
and I'd be happy to teach you if you're interested.
You'll hear about sodium rushing into cells,
and potassium
entering and leaving cells in order to allow neurons to communicate
electrolytes are critically important for the function of the nervous system and
many things that act as diuretics that promote excretion of water like caffeine
can also take electrolytes out along with in particular sodium and
sometimes the lightheadedness or the brain fog that people experience isn't just because electrolytes are low but because they're kind of out of balance.
So I like mate because it has electrolytes, it has caffeine,
it stimulates the release of this glucogon-like peptide GLP1,
and it's been a big help to me in extending that early morning fasting window
out to about noon or so when
I eat my first meal.
It also just tastes really good.
I don't drink it out of the gourd, even though I have Argentine lineage.
The gourd to me is just kind of an inconvenience I drink it out of a mug.
There's no promotional here.
I have no relationship to any year of a mate, plantations or companies.
I just happen to really like the stuff. And the fact that glucagon-like peptide-1 is enriched or is released more when you drink
mate, and the fact that GLP-1 can regulate blood sugar in ways that keep your blood sugar
in that we call it glycemic, not too high, not too low mode, is one reason why ingesting
mate is attractive to me.
If you go to South America, what you'll see, especially among Uruguayans, but also Argentines,
is people actually carry a thermos of this stuff with them around and bring it to meals
in restaurants.
That's just considered cultural convention.
It's not unusual to see that.
We don't see that so much here in the States, but I happen to really love this stuff.
I brew my own because that's the most economical way to do it.
And I really enjoy it. It can be a little bitter for some people.
The real key there, if you want to know, the Matae trick, is to not use water.
That's really boiling hot. You go just shy of boil and then it doesn't have that same
kind of tobacco-like or really acidic flavor to it.
It's a little bit just, a little bit sweeter,
although not quite sweet.
So, Urbamaate GLP1 can manage in healthy ways,
leptin levels, glucose levels, and glucagon levels
in ways that if it serves you, you might want to try.
So once again, we covered an enormous amount of material,
focused on how hormones regulate
feeding hunger and when one feels they don't need to eat, so-called satiety that you've
had enough.
As always, we covered a lot, but I could not be exhaustive about all the information related
to this topic.
It's just so vast.
For instance, we did not talk about thyroid hormone, an extremely important
hormone and pathway in the body and brain. We are going to do an episode related to thyroid
and tools to regulate thyroid, I promise. Having seen this episode, you will be able to digest
that material with far more ease. We also didn't talk about the fact that testosterone and estrogen
can impact blood glucose in
ways that are opposite to one another, that when estrogen levels are high, appetite tends
to be reduced.
When testosterone levels are high, appetite tends to increase.
So there are all sorts of interesting interplays between the various hormones, but that's much,
too much, of a deep dive for now.
Right now, we've just focused today mainly on things like
grellen, on things like melanocyte simulating hormone, incredible, powerful hormone that
can suppress appetite, on things like colicista kinin that comes from the gut and can suppress
appetite, on things like food emulsifiers, on the fact that when you're eating you are amino
acid seeking, even though you
might not realize it, that you are also seeking out particular fatty acids and particular
the conjugated linoleic acids and omega-3s.
So I tried to give you a number of actionable tools.
Many of them are behavioral, behavioral.
Some of them are based on supplements or even prescription drugs.
Again, always do what's best for your health and do that in company with a healthcare professional.
I'm not a physician, I don't prescribe anything.
I'm a professor, I profess a lot of things.
And I try and share with you what I think
to be the best high quality peer reviewed literature.
So that's what I've done today.
Really appreciate your time and attention.
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And last but not least, thank you for being with us.
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I hope you explore some of the tools and that the mechanistic information that you learn today will serve you well.
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And most of all, thank you for your interest in science.
you