Huberman Lab - Essentials: Food & Supplements for Brain Health & Cognitive Performance
Episode Date: September 11, 2025In this Huberman Lab Essentials episode, I discuss science-supported nutrients that directly support brain structure, function and long-term cognitive health. I highlight specific nutrients, includin...g omega-3 fatty acids, creatine, phosphatidylserine, anthocyanins, choline and glutamine, and discuss their recommended doses and dietary sources. I also describe how taste perception, gut-brain signaling and learned associations shape what foods we prefer and crave. Finally, I share practical behavioral tools to help rewire your food preferences toward healthier choices. Read the episode show notes at hubermanlab.com. Thank you to our sponsors AGZ by AG1: https://drinkagz.com/huberman David: https://davidprotein.com/huberman LMNT: https://drinklmnt.com/huberman Timestamps 00:00:00 Food & Brain Health 00:01:32 Structural Fat & Neurons, Tools: Omega-3s, EPA; Phosphatidylserine 00:05:11 Acetylcholine & Focus, Tool: Dietary Choline 00:06:48 Creatine & Brain Health, Tool: Creatine Supplementation 00:08:26 Sponsor: David 00:09:41 Anthocyanins & Brain Function, Tool: Blueberries & Berries 00:10:52 Glutamine & Brain, Tool: Glutamine & Offset Sugar Cravings 00:12:48 Brain-Boosting Nutrients, Foods & Supplements 00:15:03 Food Preference; Yum, Yuck or Meh; Mouth, Taste & Palatability 00:19:30 Gut, Nutrients & Subconscious Signaling 00:21:56 Learned Food Preferences 00:23:36 Sponsors: AGZ by AG1 & LMNT 00:26:16 Food & Learned Associations, Tool: Unpair Artificial Sweeteners 00:30:18 Belief Effects, Satiety, Tool: Rewiring Food Preferences 00:35:48 Recap & Key Takeaways Disclaimer & Disclosures Learn more about your ad choices. Visit megaphone.fm/adchoices
Transcript
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Welcome to Huberman Lab Essentials,
where we revisit past episodes
for the most potent and actionable science-based tools
for mental health, physical health, and performance.
I'm Andrew Huberman and I'm a professor
of neurobiology and ophthalmology
at Stanford School of Medicine.
Today we are talking all about food and the brain.
We are going to talk about foods that are good for your brain
in terms of focus, in terms of brain health generally,
and the longevity of your brain,
your ability to maintain cognition and clear thinking over time.
We are also going to talk about why and how you prefer
certain foods to others.
And I'm going to talk about the three major signals
that combine to drive your food choices.
One of those signals comes from your gut
and is completely subconscious.
These are neurons in your gut that are sending signals
to your brain that you are unaware of
about the nutrient contents of the foods that you were eating.
The second signal,
is how metabolically accessible a given food is,
meaning how readily that food can be converted
into energy that your brain, not your body,
but that your brain can use.
And the third signal is perhaps the most interesting one.
It's the signal of belief.
It's the signal of what you perceive and believe
the food that you're eating to contain
and what you think it can do for you health-wise
and energy-wise.
What are the things that directly impact brain health,
and what are the foods that we can eat
that will support brain health.
Generally, when we think about neuron function
and brain function,
we default to a discussion about fuel,
the fact that neurons use glucose,
which is blood sugar in order,
and that they require a lot of it.
But before we can even consider the fuels
that neurons use in order to function,
we have to talk about the elements
that actually allow those neurons to be there
and to stay healthy,
what actually makes up those neurons.
And that brings us to what I would argue,
is the most important food element for brain function.
And that is fat.
And that might come as a surprise,
but unless one considers the water content of the brain,
which is very high,
a lot of our brain and a lot of the integrity
of the nerve cells, the so-called neurons in our brain
and the other types of cells comes from fat.
And that's because nerve cells and other cells
in the brain have a external layer.
It's what's sometimes called
a double layered membrane.
It's essentially two thin layers
that serve as a boundary between those cells
and that boundary is very important
because how things pass across that boundary
actually regulates the electrical activity of neurons,
which is the way that neurons fire and communicate
and keep you thinking and acting
and doing all the good things
that those neurons allow us to do.
And those membranes are made up of fats,
but they're not made up of the fats
that are around our belly,
around the other organs of our body.
They're not made up of storage fat.
They are made up of,
structural fat and maintaining the so-called integrity
of that structural fat, meaning the health of those neurons
is going to come in large part from the foods that we eat.
So what type of fat is it and what should we eat
in order to support that fat and those neurons?
And the answer is the so-called essential fatty acids
and phospholipids.
Now those are more or less the same thing,
but I just wanna make a very large literature,
very crystal clear.
Essential fatty acids can include
the so-called EPA variety or DHA variety.
You hear about omega-3s and omega-6s.
Most people are getting enough omega-6s from their diet.
However, most people are not getting enough omega-3s
in their diet to support healthy brain function
in the short and long term.
What are foods that are high in omega-3s
that we should all probably be consuming,
at least on a daily basis?
The number one is fish.
Now, I don't know about you,
but I'm not eating a lot of fish,
lot of fish, I will from time to time, but that's one reason why one might want to supplement
with EPAs from another source. But also, EPAs are found in chia seeds, in walnuts, in soybeans,
and other plant-based foods. You can look these up online and you'll immediately see that
there are a lot of sources of EPAs. And many of the foods that I listed off might be appetizing
to you. Some of them might be unappetizing to you or some of them you might be sort of
neutral about, but it's very clear that eating foods that are rich in omega-3s and or supplementing
with omega-3s to get above that 1.5 grams and ideally up to two or even three grams per day
of EPA can be very beneficial for cognitive function in the short and long term. The other
compound that has been shown to be directly supportive of neuronal function is phosphatidyl
serine, which is abundant in meats and in fish. So for those of you that do consume meat and
And fish, provided you're getting enough fish,
you're probably getting enough phosphatidyl serine.
For those of you that are interested in supplementing
the phosphatidyl serine, it's a relatively inexpensive supplement
that, again, is lipid-like.
So it's mimicking some of the same things
that you would get from food, but in higher concentration.
Now, after EPA fatty acids and phosphatidyl serine,
I would say third on the list of things that come from food
that can readily support brain function would be coline.
And that's because of the relationship
the coline in the biosynthesis pathway
for acetylcholine.
Acetylcholine is a neuromodulator,
not a neurotransmitter, but a neuromodulator in the brain.
So it's kind of a electrical highlighter pen, if you will,
by analogy.
That is the basis of much of what we call focus
or our ability to concentrate on a particular batch of information
that's coming in through our eyes, our ears, our nose,
or even things that we're just thinking in our head.
And not surprisingly then,
Many of the treatments for Alzheimer's disease,
which is an inability or challenges
with remembering things and focusing are drugs
that impact the acetyloline pathway
and are aimed at enhancing the amount of acetylcholine
that's available to neurons.
The primary source for dietary coline
would be eggs and in particular egg yolks.
Eggs are an incredibly rich source
of nutrients for the brain.
And that's because the egg,
actually, if you think about it,
contains all the nutrients that are required
in order for an organism to grow.
So if you're somebody who doesn't eat eggs
or doesn't want to eat eggs,
things like potatoes, nuts and seeds and grains and fruit,
they don't have as much coline as eggs,
but they do contain colines.
In general, most people should probably strive
to get somewhere between 500 milligrams
and a gram of coline per day, so 1,000 milligrams.
Next on my list of compounds that have been shown
in peer reviewed research to improve neuronal and brain function
is creatine.
Creatine can be derived from meat sources.
It can also be supplemented.
Creeteen can actually be used as a fuel source in the brain.
And there's some evidence that it can enhance
the function of certain frontal cortical circuits
that feed down onto or rather connect to areas of the brain
that are involved in mood regulation and motivation.
What is the threshold level of creatine to supplement
in order to get the cognitive benefit?
Appears to be at least five grams per day.
Now, the most typical form of creatine is so-called creatine monohydrate.
I think it's interesting that creatine supplementation of five grams per day, that's creatine monohydrate, has been shown to improve cognition in people that aren't getting creatine from animal sources.
So I personally take creatine five grams per day and have for a very long time.
I can't say that I've noticed a tremendous benefit because I've actually never really come off it.
And so I've never done the control experiment.
I take it more as kind of a baseline insurance policy for me.
but what I can say is that I generally consume these things
like EPA's, creatine, alpha-GPC to set a general context
of support for my neurons for my brain.
And of course, I also pay attention to the foods
that contain these various compounds.
So I don't actively eat additional meat just to obtain creatine.
I eat a fairly limited amount of meat.
I don't restrict it, and I do eat meat.
But I don't actively seek out creatine in my,
My diet, rather I use supplementation in order to hit that five grams per day threshold.
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Next on the list of foods that are beneficial
for brain health is one that you've probably seen pictures
of online because there seems to be a practice
of putting pictures of blueberries
and other dark berries,
next to any title that says,
foods that benefit your brain.
There are a lot of foods out there
that have been purported to improve brain function.
The interesting thing about blueberries and other berries,
blackberries, dark currents,
any of these thin skin berries that are purplish in color,
is that they contain what are called anthocyanins.
Anthocyanins actually have some really nice data
to support the fact that they improve
brain function. Now, whether or not it is direct effects on neurons or whether or not it is by
lowering inflammation or some other modulatory effect isn't quite clear. But by now, there's
enough data to support the fact that eating a cup or two of blueberries pretty often every day
or maybe you have blackberries or maybe it's black currents, that these anthocyanins are good
for us, that they are enhancing our overall well-being at a number of different levels. So we've
got EPA fatty acids, we've got phosphodidal serine,
we've got coline, we've got creatine,
and we have the anthocyanins.
And the last item that I'd like to place in this list
of food derived things that can enhance brain function
is glutamine.
Glutamine is a very interesting amino acid.
I've talked about glutamine on here before.
There's some evidence, although somewhat scant,
there's some evidence that glutamine can enhance immune system,
function. So people will supplement with glutamine or people can get glutamine from foods.
Foods that contain a lot of glutamine are things like cottage cheese. There are also other
sources of glutamine. Glutamine is rich in protein rich foods, things like beef, chicken, fish,
dairy products, eggs, but also for you non-animal food consuming people out there, vegetables, including
beans, cabbage once again, spinach, parsley, things of that sort. So those foods contain glutamine
For people that supplement with glutamine,
generally they will take anywhere from a gram
as much as 10 grams per day.
Why would they want to do that?
Well, there's also some evidence starting to emerge
that glutamine can help offset sugar cravings.
In brief, we all have neurons in our gut
that sense the amino acid content, the fat content,
and the sugar content of the foods that we eat
and signal in a subconscious way to our brain,
whether or not the foods that we are eating
contain certain levels,
of certain amino acids.
And so we actually have glutamine sensing neurons
in our gut that actually have their little processes,
their little axons and dendrites,
as we call them in the mucosal lining of the gut.
They're not just sensing glutamine,
but when they do sense glutamine, they respond
and they send signals to the brain
that are signals of satiation of satisfaction.
And in doing so, can offset some of the sugar cravings
that many people suffer from.
So that more or less completes the list of things
that at least by,
my read of the literature are things that are supported by at least three and in some cases
as many as hundreds of studies in various populations that have been explored in mouse studies
often but also in a number of human studies. I want to emphasize again that all of the things
I listed out, whether or not it's EPAs, whether or not it's phosphatidal serine, whether or not
it's the various compounds that are in berries, etc. All of those can be extracted from food.
There is not any law that says
that you have to get them from supplementation.
Supplementation can help you get to the very high levels
of those things if you wanna work on the higher end.
If that's right for you, obviously check with your doctor
before taking anything or removing anything
from your diet or supplement regime.
But in general, you can get these things from foods.
It's just so happens that for some of these compounds,
the foods that they're contained in like fish
are not foods that I particularly enjoy.
And so I rely on, excuse,
I rely on supplements in order to get sufficient levels for me.
But again, you can get these levels from food.
And the reason I made this list,
the reason that I emphasize these things
in this particular order is that they support
the structure of neurons,
they support the structure of the other cells of the brain
that make up our cognition
and that are important for our focus
and our ability to remember things and so forth.
And they are less so in the category
so-called modulatory effects.
They will also have modulatory effects on sleep,
on inflammation or reducing inflammation
throughout the body on cardiovascular function,
all of which I believe are positive effects,
at least what the literature tells us
is that none of these compounds are harming other systems
of the body provided they are taken at reasonable levels.
But everything in this list is directed towards
answering the question, what can I eat,
what can I eat,
what can I ingest by way of food
and or food supplement that can support brain function
in the short term and in the long term.
So I hope you find that list beneficial for you,
if not for use, at least for consideration.
So now having talked about some of the foods
and micronutrients that are beneficial
to our immediate and long term brain health,
I'd like to shift gears somewhat
and talk about why it is that we like the foods that we like.
We've all heard before that we are hardwired
to pursue
pursue sugar and to like fatty foods
and that calorie rich foods are attractive to us
for all sorts of reasons, surviving famines
and things of that sort.
And while that is true, the actual mechanisms
that underlie food seeking and food preference
are far more interesting than that.
There are basically three channels in our body and nervous system
by which we decide what foods to pursue,
how much to eat, and whether or not
we will find a particular food attractive,
whether or not we will want to consume more of it,
whether or not we want to avoid it,
or whether or not it's just sort of so-so,
what I refer to as the yum, yuck, or meh analysis.
And indeed, that's what our nervous system is doing
with respect to food.
So let's talk about what these three channels
for food preference are.
The first one is an obvious one.
It's taste on the mouth.
It is the sensation that we have of the foods
that we eat while we're chewing them.
And those sensations,
which are literally just somatosensory touch sensations.
You know the palidability of food
as it relates to the consistency of food.
That's important.
And as you've all heard before,
we have sensors on our tongue
and elsewhere in our mouth
that detect the various chemicals contained within food
and lead to the senses of taste,
which we call bitter, sweet, umami, salty, and sour.
The umami receptor is a receptor that responds to the sense,
savory taste of things.
So that's what you might find in a really wonderfully rich tomato sauce.
For those of you that eat meat and like meat,
really well cooked, not necessarily well done,
but properly cooked, I should say steak, if that's your thing.
And umami is present in both plant and animal foods
and gives us that sensation of savouriness.
So we have those five basic tastes.
Those are chemical sensors on the tongue
that what we call transduce those chemicals,
those chemicals literally in food bind to those receptors
and it is transduced,
meaning the binding of those chemicals to the receptors
is converted into an electrical signal
that travels in from the tongue
along what's called the gustatory nerve,
then synapses, meaning it makes connections
in our brain stem,
in the so-called nucleus of the solitary tract.
There are other nuclei back there.
Nuclei are just aggregates of neurons.
And then it sends information up
to the so-called insular cortex.
The insular cortex is a incredible structure
that we all have that mainly is concerned
with so-called interoception
or our perception of what's going on inside our body.
So it could be the amount of pressure in our gut
because of how much food we've eaten.
It could be the acidity of our gut
if we're having a little bit of indigestion, for instance.
And not surprisingly, the taste system sends information
up to the insular cortex to give us a sense,
literally, of what we've ingested,
whether or not what we're tasting tastes good or not.
What this means is that your perception of what you like
is a central meaning deep within the brain phenomenon.
It's not about how things taste on your mouth.
But as we'll see in a few minutes,
turns out that that is not a direct relationship
that is hardwired.
You can actually uncouple the preference
for particular tastes
with the reward systems in the brain.
It's actually possible to rewire one sense of taste
and preference for particular foods.
But the most important thing to understand
is that like with our hearing,
like with vision, like with smell,
taste is an internal representation
that has particular goals for you.
Your sense of what tastes good
is related to particular things
that are occurring in your brain and body,
and body and that are likely to give your brain and body
the things that it needs.
It is not simply a matter of what you quote unquote like
or what tastes good or what doesn't taste good.
Let me give you a relatively simple example
of how your body and your brain are acting
in a coordinated way to make you prefer certain foods
and indeed to pursue certain foods more.
So I just mentioned you have neurons on your tongue
that respond to different tastes,
but of course your digestive tract,
isn't just your tongue, it's also your throat.
It goes all the way down to your stomach
and of course your intestines.
There's a long tube of digestion.
All along that tube, there are neurons.
Some of the neurons are responding
to the mechanical size of whatever portion
of the digestive tract happens to be.
So for instance, how distended or empty or full rather,
it doesn't have to be distended,
how depends on how much you ate,
but how full or empty your gut happens to be,
whether or not something you,
Just eight is temperature hot, you know,
is hot in the sense of hot to the touch,
or whether or not it's spicy hot,
whether or not it's soothing,
whether or not it's kind of hard to swallow,
this kind of thing.
So you have neurons all along your gut
that are responding to the mechanics
related to food and digestion
and that are related to the chemistry of food and digestion.
There's a population of neurons, nerve cells,
in your gut that are exquisitely tuned
to the chemistry of whatever it is in your gut.
And these are neurons called Neuropod cells,
they respond to amino acids, sugars, and fatty acids.
So as your food is digested, as food lands within your gut,
neurons there are sensing what types of foods are available
and what types of things are making their way
through the gut environment.
And these particular neurons send electrical signals
up into the brain through a little passage
that we call the no dose ganglia,
that no dose ganglia is a cluster of neurons
that then go send up their own process into the brain
and trigger the release of dopamine,
which is a molecule that inspires motivation,
reward, and more seeking for whatever it is
led to their activation.
These are super interesting neurons
because what they're essentially doing
is they are providing a subconscious signal
about the quality of the food that you're eating,
what it contains, and then triggering the release
of a molecule within your brain, dopamine,
that leads you to go seek more of those foods.
So now I've mentioned two of the three mechanisms
by which we prefer certain foods.
One is from the actual tastes that we're familiar with,
the taste on our tongue and in our mouth
and the sensations that make us go, mm, or ugh,
or the yum yuck, me responses,
as I referred to them earlier.
And then there's this subconscious signaling
coming from the gut
that's really based on the nutrient content of the foods.
There's a third pathway,
which is the learned association of a particular taste
with the particular quality or value that a food has.
And this is where things get really interesting
and where there's actually a leverage point
for you to rewire what it is that you find tasty
and that you want to seek more of.
We are driven, meaning we have mechanisms in our brain
that make us motivated to pursue more of what brings
both a taste of sweetness,
but also that brings actual changes in blood glucose levels up.
Okay, so we are motivated to eat sweet things,
not just because they taste good,
but because they change our blood sugar level.
They increase our blood sugar level.
What your brain, meaning what you are seeking when you eat,
is not taste, is not dopamine,
is not even a rise in blood glucose.
What you're seeking, even though,
though you don't realize it because it's subconscious,
is you are seeking things that allow your neurons
to be metabolically active.
And this is fundamentally important
for understanding why you eat,
why you eat particular foods,
and how you can change your relationship to those foods.
We've known for a long time that there are things
that we can do to improve our sleep.
And that includes things that we can take,
things like magnesium threonate, thionine,
chamomile extract, and glycine,
along with lesser-known
things like saffron and valerian root. These are all clinically supported ingredients that can help you
fall asleep, stay asleep, and wake up feeling more refreshed. I'm excited to share that our long-time
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Now, earlier I referred to these circuits
as wired to do something.
And in biology and in particular in neuroscience,
we talk about something being hardwired or softwired.
Hardwired meaning that it's there
and it's immutable, it cannot be changed.
Softwired meaning it's very amenable to change.
The taste system and this general system
of seeking particular foods
similarly is hardwired to obtain certain types
of nutrients, it tends to like sweet things.
Most children naturally like sweet things,
some more than others.
So there's some hard wiring of preference,
but there's also some soft wiring in the system
that allows it to change.
So the experiments that were done
that beautifully illustrate that you seek out particular foods
because of the way they taste,
because of their impact on blood glucose levels,
but also on their impact on the dopamine system,
even if your blood glucose levels don't change.
So here's the experiment.
One group of subjects is given a sweet taste
of a substance that also raises blood glucose levels,
blood sugar, and dopamine goes up, not surprisingly.
Second condition, separate subjects,
consume an artificial sweetener or a non-caloric sweetener.
It is not preferred much over other substances,
but it is sweet, so it's preferred somewhat,
and it does not cause an increase in blood glucose levels.
And not surprisingly,
Surprisingly, dopamine levels don't go up.
So initially, we don't tend to like artificial sweeteners that much.
However, if subjects continue to ingest artificial sweeteners,
even though there's no increase in blood glucose level
and therefore no increase in brain metabolism,
dopamine levels eventually start to rise.
And when those dopamine levels eventually start to rise,
you've essentially conditioned or reinforced
that artificial or non-caloric sweetener,
and then subjects start to consume more of it
and they actually get a dopamine increase from it.
So that's interesting.
It says that consuming more of these artificial sweeteners
and start to tap into the dopamine system
and lead us to seek out or consume more
of these artificial sweeteners.
Now there's another condition that's been explored
and that's the really interesting condition.
And it's the condition where an artificial sweetener
is paired with a substance that can increase blood sugar
but not because it tastes sugary
like a normal sweet substance.
The natural world scenario where this would happen
would be drinking a diet soda,
which contains no calories
and therefore would not increase blood glucose,
but is sweet with a food that increases blood glucose.
And when that happens,
what you're essentially doing is tapping into the dopamine system,
this non-chloric sweet taste is paired with it,
and there's an increase in neuron metabolism.
So you have all of the components for reinforcement
And as a consequence, you get in a sort of Pavlovian conditioning
way, a situation where later,
when you ingest that artificial sweetener,
you actually get not only the increase in dopamine,
but you get alterations in blood sugar management.
I'll make this in the natural world context.
If you ingest an artificial sweetener,
say drink diet soda while consuming foods
that increase blood glucose, then later,
even if you just drink the diet soda,
it's been shown that you secrete much more insulin,
the hormone that regulates blood glucose,
in response to that diet soda.
And the simple extract or tool from this
is if you're going to consume artificial sweeteners,
it's very likely best to consume those away from any food
that raises blood glucose levels.
So if you're going to enjoy diet soda, be my guest,
but do it not while consuming food.
in particular foods that raise blood glucose
because what these studies show is that they can disrupt
blood sugar management by way of the insulin glucose system.
Studies by my colleague Alia Crum in the psychology department
at Stanford have explored the bodily response
in terms of insulin release and the release of other food
and eating related hormones, as well as overall feelings
of satisfaction, et cetera, in groups of people,
that drink a milkshake and are either told
that it's a low calorie shake
that contains various nutrients that are good for them
or a higher calorie shake
that has a lot of nutrients, et cetera.
And what they found was that the different groups,
and here again, I'm being very general
with my description of these studies,
but what they found is that the physiological response,
the insulin response, the blood glucose response,
and the subjective measures of whether or not
people enjoyed something or not,
were heavily influenced by what they were told
were in these milkshakes.
So blood glucose would go up, insulin would go up
when people were told it was a high calorie shake
with lots of nutrients, less so when people ingested a shake
that was, you know, that they were told had less nutrients
and so forth when in reality it was the identical shake.
This is incredible, this is a belief effect.
This is not placebo, right?
A placebo effect is different.
Lecebo effect is in comparison.
It's where the control condition actually influences outcomes
to a same or to some degree,
just like the experimental condition.
This is a belief effect where the belief
and the subjective thoughts about what a given food will do
has a direct impact on a physiological measure
like blood sugar and blood glucose.
Okay, so let's zoom out from this for a second
and think about how we can incorporate this
into adopting consumption of healthy foods
that serve our brain health in the immediate and long term.
What this means is obviously you want to consume foods
that you like, but because brain health is very important
and many of the foods that promote brain health
perhaps are not the most palatable to you
or desirable to you,
if you want to eat more of a particular food
because it's good for you, pair it with that other food
that provides you a shift in brain,
metabolism because that's really what your brain
and you are seeking even though you don't realize it.
How long will this take?
Well, the data really point to the fact
that even within a short period of time of about seven days,
but certainly within 14 days,
that food will take on a subjective experience
of tasting at least better to you, if not good to you.
Now, I believe this has important implications
for much of the controversy and food wars that we see out there.
Food wars being, of course,
these groups that ardently subscribe to the idea
that their diet and the things that they are eating
are the foods that are good for us
and that are the most pleasurable
and the things that everyone should be eating.
We see this with every community within the nutrition realm.
What's very clear, however,
is that what we consume on a regular basis
and what leads to increases in brain metabolism,
leads to increases in dopamine,
and thereby our motivation to eat them.
So what this really says is that what we tend to do regularly
becomes reinforcing in and of itself.
And I think in large part can explain the fact
that yes indeed for certain people,
a given diet not only feels good,
but they heavily subscribe to the nutrient
and kind of health beneficial effects of that diet.
What this emphasizes is that foods impact our,
brain and its health, but they also impact how our brain functions and responds to food.
And that is largely a learned response. We can't completely override, for instance, that certain
foods evoke a strong, the yuck component. Certain foods are truly putrid to us, but it's also
true that if we continue to eat foods that are progressively sweeter and sweeter and highly
palatable, it shifts our dopamine system because it activates our dopamine system to
to make us believe that those foods are the only foods
that can trigger this reward system
and make us feel good and that they taste good.
But after consuming foods that perhaps are less sweet
or even less savory that are not what we would call highly,
or I would say nowadays it's super palatable foods,
we can adjust our sense literally
of what we perceive as an attractive and rewarding food.
And indeed the dopamine system will reward those foods accordingly.
Put simply, we don't just like,
like sweet foods because they taste good.
We like them because they predict
a certain kind of metabolic response.
If you wanna learn more about food reward
and food reinforcement,
because it turns out those are slightly different things,
there's a wonderful review written by Ivan Dioroujo.
They have a middle author Mark Schachter and Dana Small.
It's called Rethinking Food Reward
and it was published in the annual reviews of psychology.
You can find it very easily online.
It was published in 2019.
And it's a beautiful deep dive,
although quite accessible to most people,
about how different foods and the way that we perceive them
impacts our brain and body and why we like the things we like
and how to reshape what we like.
So once again, we've done a fairly extensive deep dive
into food and your brain.
Came up with a relatively short list of what I would call superfoods.
And we also talked about food preference
and why particular tastes and particular events
within the gut and particular events within
the brain combine to lead us to pursue particular foods
and to avoid other foods
and how you can leverage those pathways
in order to pursue more of the foods
that are going to be good for you and good,
not just for your brain, but for your overall body health
and to enjoy them all.