Huberman Lab - How to Optimize Your Water Quality & Intake for Health
Episode Date: March 6, 2023In this episode, I discuss our body’s most vital and essential nutrient—water. I explain the structure of water and how it is used by the cells and tissues of our body, how much water we each need... to drink and when in order to optimize our mental focus and physical performance; and I include how exercise, humidity, heat, and caffeine affect our hydration needs. I explain how temperature and pH influence water’s physical properties and if there is any scientific basis for drinking so-called “pH water” or “alkalized water” to improve health. I explain how to test your tap water for contaminants (e.g., endocrine disruptors) and the documented problems with fluoride in drinking water. I provide options for filtering drinking water and describe different water types (e.g., reverse osmosis, hydrogen-enriched, electrolyzed reduced, deuterium depleted, etc.). Since the human body is mostly water (55-80% depending on one’s age) and water has essential roles in health, disease and cellular function, everyone ought to benefit from understanding how best to clean our tap water, hydrate effectively and in some cases, adjust the type of water we drink to allow our brain and body to function optimally in regard to health and performance. For recommended water filters, tests and the full show notes, please visit hubermanlab.com. Thank you to our sponsors AG1: https://athleticgreens.com/huberman LMNT: https://drinklmnt.com/huberman Supplements from Momentous https://www.livemomentous.com/huberman Timestamps (00:00:00) Water (00:03:33) Tool Deliberate Cold Exposure, Immersion & Showers Mood & Fat Loss (00:15:42) Sponsor: LMNT (00:19:27) Water: Physical Properties & Chemistry (00:26:32) Bonds & Water Phases, “Structured Water” (00:32:38) Sponsor: AG1 (00:34:07) Body, Cells & Water (00:37:37) Water as a Solvent, Temperature & pH (00:41:49) Water Transport in Cells, Aquaporin Channels (00:49:46) Alkaline/pH Water; Temperature, pH & Water Transport (00:55:14) Water Cellular Function, Reactive Oxygen Species (ROS) & Antioxidants (01:02:38) Tool: Baseline Hydration (01:11:35) Tool: Hydration & Exercise, Galpin Equation (01:15:40) Tool: Hydration, Sauna, Humidity & Sweat; Thirst, Caffeine (01:19:15) Hydration; Cognitive & Physical Performance (01:23:53) Tool: Water Filtration; Nighttime Urination (01:29:35) Tap Water Tests, Disinfection Byproducts (DBPs), Fluoride & Thyroid Health (01:37:18) Tool: Water Filters (01:44:18) Tool: Resting Tap Water & Sediment (01:48:13) Tool: “Hard Water”; Magnesium, Calcium & Cardiovascular Health (01:53:40) Water Temperature (01:56:42) Water Types: Distilled, Reverse Osmosis, Hydrogen-Enriched (02:03:26) Hydrogen-Enriched Water, Magnesium, Optimize Hydration (02:11:13) Tool: Molecular Hydrogen Tablets, Water pH (02:14:05) Structured Water (02:16:39) Tool: Water Pipes, Faucet Filter (02:19:42) Zero-Cost Support, Spotify & Apple Reviews, YouTube Feedback, Sponsors, Momentous, Social Media, Neural Network Newsletter Title Card Photo Credit: Mike Blabac Disclaimer
Transcript
Discussion (0)
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. Today we're discussing water. Now to some of you water might seem like a boring topic
But I assure you that water is anything but a boring topic. In fact, water as a substance is
But I assure you that water is anything but a boring topic. In fact, water as a substance is incredibly interesting for a variety of reasons.
And I'll explain today.
In fact, we are going to discuss the physics and chemistry of water, and I promise to make
it accessible to anyone and everyone, regardless of whether or not you have a physics or chemistry
background.
And I will discuss how your body needs and utilizes water, depending on what type of water you drink, the temperature
of that water, when you drink the water, and indeed how you drink that water.
Water is actually a pretty controversial topic.
In fact, in preparing for this episode, which took me several months, in fact, I ran into
highly contradictory information and had to go on some real deep dives in order to
ferrit out the best and most accurate knowledge for you.
I also found that there are generally two camps of people out there
in terms of how they think about water and the consumption of water.
One camp, generally speaking, is of the mind that tap water is completely safe.
Perhaps it needs a little bit of filtering, but that in most areas of the world,
if it runs out of the tap,
and unless there's a warning sign directly above the faucet,
that you can drink the tap water.
The other camp seems to be the camp
that does not trust anything that comes out of the tap,
and is excited by, and in fact relies on things
like reverse osmosis, deuterium depleted,
hydrogen rich, or other forms of water that sometimes can
be very expensive or at least involve some substantial steps in order to clean filter,
alter the chemistry of, or in some other way adjust before they are willing to consume
it.
So, today what we're going to try and do is to address all the stances around water.
For instance, we will discuss whether or not tap water
is indeed safe, and I will give you some tools that will allow
you to address whether or not the water coming out of your tap
is safe, as well as some tools that will allow you to address
how to clean that water.
If indeed, it does need filtering and cleaning,
in particular, for things like fluorides and endocrine disruptors,
which it turns out are quite prominent in a lot, not all,
but a lot
of tap water sources.
I will also talk about the more, quote unquote, esoteric forms of water that I mentioned
a few minutes ago.
So I will go systematically through the list of distilled, reverse osmosis, spring water,
deuterium depleted water, high pH water.
And for those of you that are already screaming out as you hear this, oh, no, he's going to
tell us that pH water can alter the pH of our body in helpful ways.
I'm not going to tell you that.
But I will tell you that the alkalinity or acidity of the water, that is the pH of the
water that you drink, has a profound impact on your ability to absorb and utilize that
water.
And the impact that those water molecules have on specific biological systems.
So it turns out pH is very important, but not for the reasons that you've probably heard
about previously.
I will talk about how the temperature of water that you drink does indeed turn out to
be important for the rate of absorption of that water and its impact on the cells, tissues
and organs of your body and thereby your health.
And I will talk about various zero cost and low cost tools that you can use in order to
get the most out of the water that you drink.
And finally, I will talk about when and how to hydrate your body best.
Before we dive into today's topic, I want to share with you some very interesting results
that were just published on the use of deliberate cold exposure to benefit fat loss.
Now, deliberate cold exposure is a topic I've covered before in this podcast.
We have an entire episode about that
that I've linked in the show note captions.
Deliberate cold exposure can be done by way of cold showers
or immersion in cold or ice water up to the neck.
That's typically the ways that it's done.
It has been shown to reduce inflammation,
to increase metabolism.
And I think some of the most exciting results
that have been published are the results,
certainly in humans, showing that deliberate cold exposure can increase the release of
so-called catacolomines, which are dopamine, noraponephrine, and epinephrine, and those increases
in those three molecules are quite long-lasting and lead to substantial increases in mood and
focus throughout the day.
Now, many people out there hear about deliberate cold exposure and cringe.
Other people hear about it and cringe because they've heard that deliberate cold exposure,
especially by way of immersion in water, can block the adaptation to strength or hypertrophy
training.
What I mean by that is, yes, indeed, there are data showing that if one gets into very
cold water up to the neck in the six hours, any
time that is in the six hours after strength or hypertrophy training, that some of the
strength and hypertrophy increases that one would observe are blocked by that deliberate
cold exposure.
However, after six hours does not seem to be a problem.
So it can be done on other days besides the strength and hypertrophy training.
It can be done before strength and hypertrophy training.
It can be done after endurance work.
And I should mention that it does not appear
that cold showers disrupt the adaptations
to strength and hypertrophy training,
even if they are done immediately
after strength or hypertrophy training.
Okay, with that said, many people do enjoy
the effects of deliberate cold exposure in particular
for those increases in mood and alertness that are
the consequence of those increases in the cataclysmines dopamine, norepinephrine, and epinephrine.
And again, those increases are very long lasting. So it's not just during the exposure to cold,
it is for several hours, up to four, maybe even five or six hours, depending on how cold and how long
the deliberate cold exposure happens to be. Again, there's a lot to say and explore
about deliberate cold exposure.
So again, I'll just refer you to the episode
on deliberate cold exposure.
If you want to explore the mechanisms
and the positive health outcomes,
some of the controversies within the data, et cetera,
within that episode.
Meanwhile, I definitely want to share with you
the results of this recent study that just came out.
The title of this study is Impact of Cold Exposure
on Life Satisfaction
and Physical Composition of Soldiers. The reason this study is very interesting is that it's one of
the few studies that used, I should say, explored both deliberate cold exposure by immersion in cold
water, as well as deliberate cold exposure by way of cold showers as it relates to weight loss.
Now, there's already data out there on the effects of deliberate cold exposure and metabolism.
And here I'm mainly referring to the beautiful work of Dr. Susanna Soberg and colleagues
in Scandinavia that showed that people that do 11 minutes total of deliberate cold exposure
by immersion and cold water up to the neck per week.
So 11 minutes per week total spread out across some different sessions by way of getting into water that's uncomfortably cold up to the neck and then getting out and then doing that several times
per week to hit that 11 minutes or more threshold. And this is very important. We'll come up in a moment in
the context of this new study and warming up not by getting into a warm shower, which is frankly what I do
after my cold showers or getting into the ice bath or which is frankly what I do after my cold showers, or
getting into the ice bath or cold water immersion, but rather forcing their body to warm up naturally
by using its own metabolic abilities.
In those studies, they observed substantial increases in brown fat stores, which are fat
stores that you really want around the heart and clavicles, increases in metabolism that were quite dramatic, in my opinion, and
that could be very beneficial for allowing people to feel more comfortable at
cold temperatures when they're not in cold water and on and on. So lots of
benefits shown in that study. In this study, what I thought was particularly
interesting is, again, they explored both immersion in cold water and cold
showers and the duration of cold exposure
that they found led to substantial fat loss, especially around the abdomen, was very brief,
deliberate cold exposure. Let me give you a few details about this study. The study involved
49 subjects that include both males and females. This is also really important. The beautiful work of Susanna Sobergen colleagues, as far as I know, only looked at males. This study looked at males and females.
They were 19 to 30 years old, and they basically were two groups. People are either
were assigned to get deliberate cold exposure, or they were not assigned to deliberate cold exposure.
The form of deliberate cold exposure involved one session per week of cold immersion
in cold water up to the neck and to just give you a sense of how cold it was. It was three degrees
Celsius, which translates to about 37.5 degrees Fahrenheit. That's pretty darn cold, but it was
only for two minutes. Okay, so one session at three degrees Celsius, otherwise known as 37.4 degrees Fahrenheit,
for two minutes every week, once a week. In addition, the same subjects did five cold showers per week,
or a minimum of five cold showers per week. And those cold showers were slightly warmer than
the immersion in cold water condition.
So they were 10 degrees Celsius, approximately, or 50 degrees Fahrenheit.
Still pretty cold.
And the duration of that cold water exposure in the shower was just for 30 seconds.
Okay, so this is interesting to me because many people don't have access to cold water
immersion.
They might not have a nice bath or any place they can do that,
but most people do have access to a cold shower of some sort.
Plus, I think most people could do probably one ice bath per week
or find a place where they could get into cold water safely.
Now, I should point out that some people will not do well
going into 37.5 degree Fahrenheit,
AKA three degree Celsius water, having never done anything like
this before.
So if you're going to try and employ these sorts of protocols that were used in the study,
I do recommend that you ease into it over the course of a week or so and become somewhat
adapted to the shock of cold water exposure.
So maybe start at, you know, 50 degrees Fahrenheit, kind of easier way back in terms of the cold
water immersion, especially. Now, another critical feature of this study is as with the beautiful work by Suzanisoburg,
the subjects were told to warm up naturally after the deliberate cold exposure. So they basically
hung out outside of the cold water immersion or outside of the cold shower for 10 minutes
after they were exposed to the cold in their bathing suit,
or I'm assuming they were wearing something. But the point is that you are not going from
deliberate cold exposure directly into a hot shower or a sauna or something of that sort. So again,
their bodies were forced to heat up again naturally after the deliberate cold exposure. But after
the 10 minute period,
they were able to do whatever they wanted, essentially reclothe, take a warm shower, and so
on and go about their day.
Now, the results of this deliberate cold exposure protocol, again, two minutes in cold immersion
at three degrees Celsius, 37.5 degrees Fahrenheit, plus five cold showers per week of two minutes
long, a little bit warmer, 10 degrees Celsius,
50 degrees Fahrenheit.
Now, the deliberate cold exposure used in this study caused many different statistically
significant positive changes.
They had a very extensive questionnaire that related to mood, everything from levels of
anxiety, to sexual satisfaction, and on and on.
In fact, they saw a statistically significant improvement in sexual satisfaction in the subjects that were exposed to deliberate cold exposure, not in
the control group. Although they didn't look at this, chances are those improvements in
sexual satisfaction were the downstream consequence of the known increases in testosterone and
free testosterone that occur in both men and women who do this sorts of deliberate cold
exposure. Again, testosterone being important hormone for libido in both men and women who do this sorts of deliberate cold exposure. Again, testosterone being important hormone for libido in both men and women.
They also saw improvements in regulation of anxiety, which I think is very
interesting, given that the deliberate cold exposure often causes people anxiety,
but here and in other studies, we've seen it can lead to an
a better ability to buffer against anxiety
in the normal happenings of everyday life.
Perhaps the most interesting and significant results
that they found in the study, however,
were that in particular in men,
there was a reduction in waist circumference
following eight weeks of this deliberate cold exposure,
as well as a 5.5% on average, 5.5% reduction in abdominal fat
that was quite statistically significant when compared to the other groups. Now, why there was no
observed reduction in abdominal fat or waist circumference in the female subjects isn't clear,
could have to do with just the way that body fat is stored and metabolized in females versus males,
that is going to be a topic for future exploration.
So I do think the study is very interesting because when you look at the landscape of science
and discussion around deliberate cold exposure, I think there's a general consensus now that
deliberate cold exposure can change one sense of mood and well-being through these increases
in catacoleumines that I mentioned earlier.
But the impact on metabolism itself has been somewhat controversial because the overall
changes in metabolism that are observed while statistically significant in many studies
have not ever really been shown to translate into weight loss or body fat loss in any kind
of specific way.
And of course, a great advantage of this study is that by exploring soldiers, they were able
to really hold constant a number of other features like the amount of daily activity that those
soldiers are exposed to, their diet, their living conditions, and so on and so forth.
So at least in so far as human studies are done, it's a very well controlled study.
We'll provide a link to the study in the show note captions.
And for those of you that are thinking about employing the protocol that's used in this particular paper or combining
it with existing deliberate cold exposure protocols, to me it seems pretty straightforward
and of pretty minimal time investment. Just two minutes of deliberate cold exposure by
way of water immersion up to the neck and five times a week of 30 seconds each of deliberate
cold exposure by way of cold shower.
And just a quick mention about cold showers.
If you're going to use cold showers
to do deliberate cold exposure,
you're going to want to stand under the shower itself, right?
And essentially have it hit your head,
the back of your neck and your upper back,
which is where most of your brown fat stores
are concentrated and it turns out that cold exposure
to those regions of the body in particular are going to trigger the adaptation of increased brown fat stores are concentrated, it turns out that cold exposure to those regions
of the body in particular are going to trigger
the adaptation of increased brown fat stores,
which involves increases in mitochondria
and those fat again.
This is not the blubbery fat beneath the skin.
This is the fat that acts as kind of an oil
in the furnace that is your thermogenic properties
of your body to generate heat and burn off
so-called white adipose tissue elsewhere in the body.
Now, anyone that understands the laws of physics and thermodynamics will be saying, wait,
in order to get fat loss, you need to have a caloric deficit.
Calurising calories out still applies.
And yes, that's absolutely true.
We can only conclude on the basis of the results of this study that the people that lost
body fat were indeed in a
caloric deficit, presumably, because all other factors were
held more or less constant in this group of soldiers,
presumably, because the deliberate cold exposure itself elevated
metabolism, thereby increasing the calories out component of
the calories in calories out equation, which of course,
governs the rules of weight loss and body fat loss as well.
Before we begin, I'd like to emphasize that this podcast is separate from my teaching
and research roles at Stanford.
It is, however, part of my desire and effort to bring zero cost to consumer information
about science and science-related tools to the general public.
In keeping with that theme, I'd like to thank the sponsors of today's podcast.
Our first sponsor is Element.
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That means plenty of salt, magnesium and potassium, the so-called electrolytes, and no sugar.
Salt, magnesium and potassium are critical to the function of all the cells in your body
in particular to the function of your nerve cells, also called neurons.
In fact, in order for your neurons to function properly,
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Let's talk about water. Let's start off by answering the question, what is water? Water
is of course H2O. Most everybody knows that from an early age. But what H2O means is that
each molecule of water consists of two hydrogens and one oxygen.
Now the physical arrangement of those two hydrogens and one oxygen turns out to be really important
for how water functions in the body and frankly elsewhere in our world and life.
If you were to make a piece symbol, that is to put up your index finger and your middle finger,
simultaneously. In fact, I'm going to recommend you do that now That is to put up your index finger and your middle finger simultaneously.
In fact, I'm going to recommend you do that now unless you're using your hands for something
else important, in which case do it later.
Well, if you make that piece symbol and you look at your hand, you have a pretty good impression
of what an individual water molecule consists of, which is H2O, two hydrogens and an oxygen.
And with that piece symbol, the fingers, or the tips of your fingers, rather, are going
to represent the hydrogens.
Your fingers, that is the length of each of those fingers, is going to represent the
electron bonds to the oxygen.
And the palm of your hand and the fingers that are down are going to represent the oxygen.
Okay.
Now, what's important about that visual impression or visual image of the individual water molecule
is that it is polarized.
That is, the hydrogens over on one side, both of them are over on one side, and the oxygen
is over on another.
And what's really important about water molecules being polarized is that they can bind to one
another by way of that polarization.
And this has to do with something that we all kind of learned in chemistry at one point,
but many of us forgot.
We didn't even understand it the first time around, which is that positives and negatives attract.
So when you have individual water molecules, they have the opportunity to interact and essentially
bind to one another.
And they bind through what are called covalent bonds.
Covalent bonds are relatively weak bonds.
And so as a consequence, water can change its confirmation.
However, covalent bonds are strong enough
that water actually can maintain some structure
and that structure will vary, of course,
depending on its temperature.
So what you need to know about water is that, indeed, it consists of lots of individual
H2Os, and those H2Os can arrange themselves in different ways, and that temperature is
a strong determinant of the arrangement of those water molecules, that is, they're bonding
to one another, and in fact, even they're spacing between those bonds.
So again, even if you don't have any chemistry, stay with me because you'll definitely understand
this.
Water can exist in at least three forms and maybe four forms.
We know that it can be liquid, of course.
It's really what we think of when we think of water.
It can be gas, so we think of steam, right?
So if you heat it up, it takes on a, not a semi solid or a semi liquid form.
It takes on this property of steam or gas.
So when you see steam or when you breathe on a cold day
through your mouth or through your nose
and you see your air, those are water molecules
that are condensing, that is bonding in certain ways
based on differences in temperature
between the inside of your body and the outside air.
And of course, it can be a solid, it can be ice.
Now ice is fascinating and important in understanding how water works.
And this will become relevant later when we think about how water works within the body
as well, especially how different temperatures of water impact the health and behavior of
ourselves.
And the most important point to understand about water in its solid state is that unlike
most substances, when water is in its solid state is that, unlike most
substances, when water is in its solid state, it is actually less dense than when it's in
its liquid state.
So just think about that.
Most substances, like most metals, for instance, when they are in a solid state, they're
more dense than when they are in a liquid state.
So for instance, if they're in a solid state, they will sink in a container filled with their liquid form,
not water.
Water is very interesting because as you cool water
and water transitions from a liquid to a solid,
it still binds, that is, it conform bonds
between those different molecules of water,
but the spacing between those H2O,
so again, those P symbols with hands. If you had a bunch of those, if you had a thousand hands,
all making P symbols, they can bond to one another, but when it's cold, those bonds are actually
made further apart from one another. And as a consequence, ice, as we all know floats in water. In other words put very simply
water is unusual and special in that in its solid form ice it is actually less dense than when
it's in its liquid form and that's why ice floats in water. Now this is important not just our
our biology but to all of life because if you about it, if it were not the case that water
is less dense in its solid form ice than it is in its liquid form, the bottoms of our
oceans would be covered with thick sheets of ice. And if that were the case, you can be
absolutely sure that life would not exist on our planet the way that it does. And there's
a good chance that we would not exist as a species because so much of what allows us
to exist on this planet and the other animals
to exist on this planet relies on photosynthesis pathways
and plants that are dependent on the sun and interactions
with the oceans and lakes and other bodies of water.
And of course, the ice caps are vitally important.
That is the presence of ice, especially at the poles, but elsewhere in bodies of water as well. So icebergs are
a critical part of the ecosystem that allows for everything from photosynthesis to the
ability of certain animals to extract food from each other and from their local resources.
Now, there's a whole discussion to be had there, but the important point for now is that
the physical properties of the bonds between water that are made and changed depending
on temperature turn out to be essential for us to be present on this planet at all, and
for ourselves to function in the ways that they do for sake of health and for sake of disease.
And we'll explore this later when we talk about the critical relationship between temperature, pH,
which is the relationship between alkalinity,
how basic or acidity, how acid, a given liquid,
or in this case we're gonna be talking about water is,
and the ways that our cells can or can't use water.
So I realize that this is a fairly in-depth
for those of you that don't have much of a background
in chemistry. I've tried to keep it really top contour, but if you can make a piece symbol, or if you can
just imagine a piece symbol in your mind, and realize that that's a water molecule and that those
water molecules combined to one another through bonds that are relatively strong, but weak enough that
they can be broken if they need to, and that the temperature that those water molecules are exposed to changes the distance between those
bonds, and that's what allows ice to float in water.
Then you are going to have no problem with the remainder of the discussion today.
In fact, you will also have the ability to understand things that you've observed many
times over, but perhaps have never thought about or were really understood, which are, for instance,
that water has a certain level of surface tension. For instance, if you've ever been to the ocean,
and the waves are coming in, what you'll notice is, if you walk on the dry sand or gravel of pebbles
that is, of the ocean, it's very easy, right? I mean, the pebbles move down or the sand moves
down, it depresses a little bit due to the weight of your body. But as you get closer to the water,
you're gonna sink deeper because that sand
is more saturated with water.
But at some point, you won't be able to actually walk
on top of the water, right?
It has been said that Jesus walked on water.
There's the so-called Jesus Christ lizard.
So named because it can actually walk on the surface of water.
A leaf can float on the surface of water. Under some conditions, a leaf can float on the surface of water under some conditions, a coin can float on the surface of water.
If you make coffee in the morning, you can actually take a spoonful of that hot coffee and pour a little bit on the surface of your coffee and you'll notice that it will be up and you'll get little round spheres of water.
Those are little water molecules bound to one another that spin on top of the surface before they sink under. That has everything to do with the bonding between water that's dependent on temperature, but also as with
the difficulty for essentially everybody to walk on water,
or for animals to walk on water, the surface tension of water allows certain things to float there,
or to stay at the surface, but there's a very thin layer of water molecules
at the surface of water that are more dense
than the water that resides at deeper depths.
And that's why most things, including us,
sink in water.
We are more dense than water.
Now, I did mention earlier that there are three forms of water.
There's the ones that we all are familiar with,
the solid liquid and gas forms of water.
However, there are data mainly from Gerald Pollock's laboratory at the University of Washington
that have described this so-called fourth phase of water, which is structured water.
And we'll get into this a little bit later because structured water has really been a prominent
topic in the, let's call it the water health of fissionados.
It's a heavily-devated topic as to whether or not
structured water is somehow better for ourselves
if it exists within our bodies.
We'll get into that in full detail later.
But the whole notion of structured water
is that in the presence of certain solids
or certain liquids, the confirmation of water,
that is the water molecules, actually change somewhat.
This has been demonstrated.
Whether or not it has relevance
to the biological function of our body
is a different issue.
But we know that there is this fourth phase
of water called structured water.
Structured water is a fairly complicated topic,
but we can make it very simple for sake of today's discussion.
I mentioned earlier that opposite poles attract,
that is, positives and negatives attract,
and typically things that are negatively charged when presented with another negative charge either
Repel or don't attract things that are positively charged in the presence of another positive charge also tend to repel
This is the basis of magnets either sticking to one another or repelling from one another
There's also the idea that human beings were opposites attract, but that's a different episode that we need to do in the future
The point here is that structured water is a unique condition in which the local environment
that these water molecules happen to be in allows positive charges between different water molecules
to attract one another. So again, whereas normally it's positive and negative is that it's tracked. In the configuration that we call structured water,
positives and positives attract, and form bonds that
are stronger than the typical bonds that
would be formed between water molecules.
And just as it kind of prelude to our discussion
about structured water as it may or may not relate to health
later, there are a number of people
that believe that within the body,
because of the presence of certain liquids and solids,
that the water within our cells,
and in particular within the interactions
with so-called organelles, organelles are things like mitochondria,
the Golgi apparatus, they fancy names.
These are the things within cells that allow cells
to do everything from make proteins to traffic proteins
out to the surface of cells
things like neurotransmitters and receptors and so on. A lot of people who are interested in structured water as it relates to biological function have I
prophesized or like to debate rather
whether or not in the body water is not just present in its liquid form
or gaseous form. We know it's not present in its solid form unless you
or gaseous form. We know it's not present in its solid form unless you gulp down some ice cubes, for instance.
But there is a cohort of people out there including some fairly accomplished scientists that believe that within the body
the organelles of ourselves act as a substrate for water to exist in this fourth form, this structured water form, and that's led to this whole niche industry of people
who are proponents of consuming so-called structured water.
Again, we'll get to that a little bit later.
So now you know what individual water molecules consist of.
When you hear H2O, hopefully you'll get that visual image
in your mind of an individual water molecule being the piece symbol
and a bunch of those binding to one another
through these relatively weak bonds,
but strong enough that certain things can take place
like surface tension.
Keep in mind that surface tension of water may relate
to either standard bonds between water or this fourth phase.
That's heavily debated still.
But we certainly know that, for instance,
if you were to take a piece of wax paper or glass
and you were to pour some water on it,
you would notice that the water would beat up
or kind of aggregate at particular locations.
When you see that beating up
or the aggregation of water molecules
on a particular surface, you're seeing two things.
This is actually kind of fun.
The next time you see it, you'll know that the aggregation,
the beating up of water with itself,
so individual water molecules or many water molecules
are aggregating at one location and making a bead of water.
That's due to these bonds, these covalent bonds
occurring between water molecules.
But also you'll notice that on a vertical pane of glass,
say in rain or on your windshield,
that the water will look almost like it's sticking to the glass.
And that's because there are actually bonds
between the water molecules that have beaded up themselves
and the glass.
So water can not just bind to itself, it can also bind to certain surfaces, and the fact
that perhaps if you drive your car, if you were to tap the window, or if a big enough bead
of water formed on a window that it would start to drip down, that's because those bonds
with the surface are strong, but they're not so strong that it's stick at that location. Quite different than water that is in its solid form, ice, that can actually
really adhere. If you've ever had a scrape ice off a windshield, so for those of you living
cold regions, you're familiar with this, have this scrape ice off a windshield. You realize that the
bonds between water and its solid form and different services is quite a bit stronger than the bonds between
different water molecules with each other or the bonds between water and different services when
they are warmer. Okay, so I do realize that for a lot of people listening, that's going to be a
pretty deep dive into the chemistry and physical properties of water. But all you really need to know
is that these water molecules are incredibly versatile
and can bind to each other and can bind to different surfaces and can allow things to
float or to sink or even to move across surfaces of water based on the three, perhaps four
different states that water can be in.
And that versatility that you observe in the natural world on window panes and rain
and clouds and hail and ice and snow and scraping
ice off your windshield in the cold of winter and perspiration and so on.
All of that is fine and good, but realize that almost all of those same sorts of properties
of water become extremely relevant when thinking about how your body actually utilizes water.
And the key thing here is that temperature
and the so-called alkalinity or acidity,
that is the pH of water,
turned out to be very important determinants
of how water is used by the cells of your body.
In fact, as I'll describe in a moment,
we have entire sets of biological mechanisms
solely devoted to trying to get water into our cells
in very specific ways,
including at specific rates, and to use water
in different ways, because, as you've probably heard before,
we are mostly water.
What's kind of interesting to me,
and what I found researching this episode,
is that the percentages of our cells and bodies
that are purported to be water is a pretty broad range.
Some people say we're 55% water.
Other people say we're 70% water.
Some people say we're 95% water. Other people say we're 70% water. Some people say we're 95% water.
The exact percentage doesn't matter so much.
And really just boils down to whether or not the person that's stating that percentage
is talking about how much water is present in our cells in body at a given moment versus
how much water was involved in the process of creating the sorts of proteins and other
things of our body that are required
to have hair cell, skin cells, brain cells, et cetera.
So if you really want a number out there,
I can't give you a single number.
If you want to be accurate, it's going to have to be a range.
And basically, we are anywhere from 70% to 90% water,
depending on how you define being water.
That is, whether or not you're talking about water being
present in cells in its liquid form, or maybe in this fourth structure water form if you're
of the mind that that exists within us. And whether or not you're talking about water that was used to create a given protein like a receptor or a
transmitter or whether or not you're talking about the water just being water as H2O. Okay, so again it's's very easy to go down that rabbit hole, and this is part of the reason
why there's such a wide discrepancy of assertions as to how much of us is water, but let's be
direct.
Most of our body is water, and there isn't a single other molecule in the universe that
we can look to and say that it has as important a role in our health and biology, and frankly,
our presence of life
on Earth at all, then water.
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Okay, so now at a minimum, everyone out there should understand that water has a particular structure.
So when you hear H2O, you can kind of imagine that structure.
And that the water molecules can change their confirmation
that is they can bind to other water molecules
and it turns out they can bind to other things
and actually change the confirmation of other things.
A good example of that is something we're all familiar with,
which is water's ability to dissolve certain substances like sugar or salt. And that is because
salt molecules or sugar molecules are what we call hydrophilic. They like water. And when we say
they like water, it just means that the chemical structure of salt, sodium, or the chemical structure of, say sucrose, like table sugar, can actually interact with
the hydrogens and oxygens of water, and can change those salt molecules or sugar molecules
turning them from solid into liquid, essentially creating what are called solutes, which is basically
the dissolving of solids into liquid, essentially creating what are called solutes, which is basically the dissolving
of solids into a liquid solution.
In fact, water is one of the best solvents on the planet.
In fact, water is better at dissolving many solids than is acid.
That's how incredible water is.
There are a number of reasons related to the chemistry of water that can explain that. But as we transition from talking about the physics
and chemistry of water to how water actually behaves
within our body and contributes to our health
or to disease, depending on the case,
it's important to understand that molecules,
such as sugar and salt can be hydrophilic
or as we know, oil and water don't mix.
That's because oils, lipids, are so called hydrophobic.
What's hydrophobic?
We'll just think, ah, phobic.
Certain molecules such as lipids
don't dissolve well in water.
And we all intuitively understand that.
If you take some olive oil, for instance,
and you put it into a little glass of water,
it'll likely float or beat up or form a little spherical or amoeba-like shapes within
the water, and that's because oil lipids are hydrophobic.
So different substances out there are either going to be more hydrophilic, that is they
are going to have a greater propensity to interact with water and bind with the different aspects
of the water molecules,
or hydrophobic, to have less of a propensity to interact with and bind with water molecules.
And I'm sort of been alluding to this numerous times throughout this podcast already,
the temperature of water, and the pH, that is, the alkalinity or acidity of water,
will have a strong impact on whether or not a hydrophilic
or hydrophobic substance will have a greater or lesser tendency
to interact with water.
You all know this intuitively as well.
If you've ever tried to dissolve, say,
a big tablespoon of sugar in very cold water,
you'll notice that the grains don't dissolve as quickly as when you take
that big tablespoon of sugar and put it into a warm or hot cup of water. And that's because
the temperature of water actually changes how well that sugar molecule is able to change
its confirmation and interact with the water molecules. Likewise, if you want to get something that's really hydrophilic
into an aqueous, that is a water-containing solution,
the temperature is also going to strongly impact that.
Now, there are a near-infinite number of examples
of how temperature and pH impact the tendency
of hydrophilic and hydrophobic substances
to dissolve in water or not.
We're not going to go into all those details.
But as we migrate from our discussion about the physics and chemistry of water into how
water behaves within our body, which is what we're going to do now, and then as we continue
into the third part of our discussion, which is why and how certain types of water that
some of you are familiar with, like different pH water, distilled water, reverse osmosis water,
why those different types of water
are thought to and in some cases do in fact change the ways
that our cells function for better or for worse.
All of that will come together and make sense for you.
Okay, so all the cells of your body, every cell,
even your bones, that is the osteoblasts
and the other cells within your bones, your bone marrow,
your red blood cells, your white blood cells,
your neurons, your nerve cells, your liver cells, your kidney cells, all of them require water.
In order to get the proper amount of water into those cells, there are basically two ways
that water can access those cells. We zoom out for a second and ask ourselves, how does water
actually get into the body? Most of us just think, oh, we drink that water into our body. Of course,
that's the main way. We can also breathe water molecules into the body, most of us just think, oh, we drink that water into our body. Of course, that's the main way.
We can also breathe water molecules into our body through humid air.
When you hydrate your cells, that is, when you're bringing water into your cells, that
water needs to move from your gut and into the bloodstream and eventually into the individual
cells, whatever cell type that may be.
They're basically two ways
that water can access those cells.
The first way has been known about for a very long time
and that is so-called diffusion.
Now the outside of most cells is made up of fatty stuff,
lipid.
So for instance, neurons, nerve cells,
have a lipid by layer, it's two layers of fat.
And you already know that fat lipid is very hydrophobic.
Okay?
Now, that turns out to be not a problem, but a solution for how water can get across that
lipid barrier.
Why?
It is the fact that water can change its confirmation and lipids can change their confirmation just
enough so that the bonds between water and the bonds between those hydrophobic lipids can change their confirmation just enough so that the bonds between water and the bonds between those hydrophobic lipids can interact, allowing the water molecule to basically
pass through the lipid because it can bond very weakly, or in some cases not at all, but
very weakly to those lipids, and then be pushed through to the other side.
Really incredible if you think about it.
If there was too much of a hydrophobic relationship between the lipid and the water,
the water would come up to the surface of that
of that fatty outside of of our cells and then would be repelled away from it or would just stay there right at the surface.
And that would be no good because we actually need that water to diffuse across the cell membranes where actually it's a
double cell membrane as I mentioned before, two layers. So water and lipids of
cells can interact
with just enough affinity
that the water molecule can diffuse across those cell membrane barriers.
But, and this is an important,
but the diffusion of water molecules
across those lipid barriers on the outside of cells
is a fairly slow process
compared to the other way that water accesses cells. And the other way that water accesses cells.
And this other way that water accesses cells is really something that was just discovered
about 10 years ago.
So this is a fairly recent discovery, which turns out to be a fundamental discovery, which
is the presence of what are called aquaporn channels.
Aquaporn channels are basically portals through the membrane that allow water molecules to move very quickly
across cell membranes at a rate of about 1 million H2O's,
1 million water molecules per second.
And the way that water molecules move across
the cell membrane through those aquaporine channels
is very interesting, the inside of those channels,
and the way I think of these is they're literally tubes,
stuck through the membranes of cells, the insides of those channels are
very hydrophobic, allowing those water molecules to just just really quickly, almost as if in
your mind you can just imagine as if it were lubricated for the water, although it's
not really lubricated, the water molecules can move through in single file, a million
per second.
Now, why would you need two ways for water
to get across cell membranes, one fairly slow
through basic diffusion?
And again, diffusion folks is the movement of things
from a gradient of higher concentration to lower concentration,
which is just think about this as things
tend to run downhill from higher concentration
to lower concentration. They try and create equilibrium across space. So,
you know, if you had a bunch of marbles on one side of a box, they're just imagine that
these were water molecules because of the charges between those hydrogens and oxygens,
there's a tendency for those marbles to spread out and essentially take on a fairly even confirmation.
That's basically just diffusion across a space.
Water molecules will also move from higher concentration
to lower concentration across cell membranes.
And then you have these portals, these tubes
or these channels as they're called,
these aquaporn channels were water molecules,
it can move very quickly.
Now the reason why biology seems to have created
these aquaporn channels, and again, I wasn't
consulted the design phase, but the most logical explanation is that we have many tissues within
our body that often need water very quickly or need to release water very quickly.
Let's think about a couple of these, and then let's look at what the actual distribution
of aquaporn channels is throughout the body
What is an area of your body that on occasion will need to move water very quickly out of it?
You can use your imagination here
But I'll just tell you that for instance your tear glands or tear ducts
Need to release tears very quickly. So you need to take water that's stored in your body. If there's an emotional experience,
or if you look at a very bright light, for instance,
or God forbid, if you get some sort of irritant in your eye,
you're gonna start to tear up.
And those tears are the release of fluid from those tear ducts.
And so it's gonna be the very rapid release
of water from those tear ducts
through so-called aquaportin channels.
In fact, aquaportin channels are heavily expressed.
There are many of them in the cells of the so-called lacrimal glands that release tears.
In addition, we need to absorb water from the gut.
The gut has a lining and a theoleal lining.
Other cell linings, mucosal lining, and water needs
often to move very quickly from our stomach into the rest of the body. And one way that is accomplished
is through aquaporn channels that are expressed all along your gut. So the discovery of these aquaporn
channels is really highly significant in terms of understanding the different ways that water
can interact with and get into the cells of your body.
There are aquaporn channels, not just in the lacquer monglans that allow for tearing, or
within the gut, but in many tissues within your body and there even have different just
distributions within those tissues.
In fact, as one looks at the expression of the different aquaporn channels, because it
turns out there are different forms of them, Across all the cells and tissues of the body, there's really no single tissue within the
body except perhaps the bones of your body, and perhaps the ligaments to some extent that
don't have these aquaporn channels.
Some of you out there may have heard of this so-called fascia, fascia, and sheath muscles
are unique kind of connective tissue that gives some pliability and yet some
rigidity that allow for a lot of the physical abilities of your muskah skeletal system.
It's an incredible tissue.
We'll do an entire episode about fascia at some point, fascinating, fascinating tissue.
Fascia even contain aquaporn channels.
So the role of aquaporn channels in fascia probably relates to our specific needs to be able to use specific
muscle groups in particular ways, at particular times.
In other words, if you're sleeping or lying down or sitting, you're not using your musculoskeletal
system as much as if you're running or performing some repetitive behavior, it turns out that
the aquaporn channels in certain tissues like the fascia can be used when we transition
from low mobility states to high mobility states,
allowing more perfusion or access of water into particular cells of the body
when we need it. So just fascinating, fascinating channels, these aquapouring
channels. And again, only discovered fairly recently. So we're still learning
new things about our biology all the time. Now, a very important feature of the
aquapouring channel is that the movement of water molecules
across the cell membrane through those aquaporting channels is strongly dependent on the temperature
of water and the pH of water.
This becomes especially important in our description and our deep dive into so-called alkaline water
or higher pH water a little bit later.
But I'll just give you a little teaser for now
Because I'm sure that a number of people are wondering about this
If you go into the store or even a convenient store, you will see
pH water now every water has a pH right lower numbers mean more acidic higher numbers mean more alkaline or more basic
You'll see pH water that that is 7.4.
You'll see 7.8.
You'll see 9.8.
You'll see a huge range of these things.
And there are many, many different claims
about how the pH of water is important
for regulating the pH of the body.
Here's the real story.
The pH of your body, that is the pH of the cells
at different locations in your body,
is strongly, strongly, homeostatically regulated.
What do I mean by that?
It means it doesn't change that much, which means that you have very specific biological
mechanisms that ensure the pH is maintained, for instance, in the skin cells of your skin,
in the retinal cells of your eye, in your brain cells.
Now, it is true that across the body, different cells and tissues have fairly widely varying
pH.
It has been said that the pH of bodily tissues is generally between 7.2 and 7.4.
However, if you were to look at the pH of your gut and keep in mind that your gut is not
just your stomach, your gut is the entire pathway ranging from your throat all the way down
to where you excrete things out of your body, that entire pathway has different pH levels
depending on where you are along the gut and intestinal pathway.
And in fact, having much lower, that is more acidic pH at certain locations along your gut pathway,
is what allows those gut microbiota, those little microorganisms of which you have trillions
that are important for regulating everything from neurotransmitter production to hormone production
that allow them to flourish and do well.
That said, except under conditions of hemorrhage or changes in blood volume that
are of a dangerous level that can lead to seizure or even death, the pH of the rest of the
cells of your body and also those gut cells doesn't change that much on a moment-to-moment
basis.
So, if somebody tells you that you should drink alkaline water or alkalized water as it
sometimes called, in order to keep your body more alkaline and less acidic, there is essentially
no basis for that at a macroscopic level or even at a local level.
Now, what that does not mean is that the pH of the water that you drink is not important. In fact,
if the pH of the water that you drink is too low, that is, if the water that you consume is too
acidic, it will not move as quickly from your gut into the other regions of your body and therefore
the other cells of your body that require that water will not be able to access it as readily.
You've probably experienced this if you consume certain water and it feels like it's sloshing around in your stomach
or it feels like it's just somehow staying there or you feel it's presence more, not just as volume,
but it's almost as if you can feel the little waves of water along the inside of your gut.
Now sometimes that can relate to temperature, but oftentimes that can relate to the pH of that water. And it turns out it is true that water that
is more alkaline, that is pHs of 7.4 or higher, can move more readily across the aquapouring channel.
And in terms of absorption of water from the endothelial lining and the other cell type lining of your gut into the rest of your body,
it is true that higher pH water provided that pH isn't too high is going to be absorbed more quickly,
which partially explains why some people have an affinity for this higher pH water.
Now this is not to say that you need to consume high pH water in order to hydrate your body properly. I wanna be very clear about that.
However, if you are interested in what the value
of elevated pH water is, it largely has to do
with this accelerated absorption.
And as we'll talk about a little bit later,
there is also growing evidence that it can adjust
the function of certain cells that are within your immune system
and thereby
reduce certain inflammatory responses.
So I realize, as I'm saying this, some people will out there apply you think, oh no, this
guy is like a pH water proponent.
He's saying we have to drink alkaline water or buy very fancy water.
Now I want to be clear that is not what I'm saying.
And I'm also not saying that you need to purchase very expensive water in order to drive the maximum benefits from the water that you drink.
It turns out there are a few things that you can do by way of temperature and by way of
filtering water.
And a few other tricks that I'll tell you a little bit later that will allow you to increase
the absorption rate of water in the gut, which turns out to be a very interesting, but
also potentially important thing to do for not just reducing inflammation,
but also making sure that you're getting proper hydration of different cell types in your
body, including rapid hydration of your brain cells, which, as we'll also talk about in
a few moments, can greatly enhance cognitive function.
Okay, so we've talked about how water can get into cells.
There are two ways, diffusion and movement through these aquaporn channels.
We've earmarked the discussion that the temperature and the pH of water, that is the confirmation
of water.
And here I really want to embed this in people's minds that when we talk about temperature
of water and pH of water, we're really talking about the arrangement of those H2O's, those
water molecules.
So keep that in mind.
We've covered how water can get into cells through those two different ways diffusion and through the rock reporting channels.
What we haven't talked about is what happens to water once it's in cells.
And this is very simple to explain. Once water is inside of cells, it's going to be incorporated
into the different proteins and organelles. Again, organelles are things like mitochondria,
the nucleus of the cells, which contains the the DNA, and so forth, in different ways, depending on which proteins are there and how hydrophilic
or hydrophobic those proteins are, or in some case, aren't.
That's an entire landscape of protein to water-specific interactions, none of which we need to
go into in any specific detail now.
But the one thing that we do need to realize and keep in mind as we go forward is that many
of the biological processes in our body that involve the movement of molecules such as water
and interactions with proteins are going to involve the bonding or lack of bonding between water
molecules and proteins.
And anytime we're talking about bonding of one thing to the next at the level of chemistry
or biology for that matter, because they're really the same thing.
We're talking about whether or not there are electrons present or whether or not there
are charges that are opposite or the same and on and on.
If you've ever heard of so-called reactive oxygen species,
what are ROS's or reactive oxygen species,
or so-called free radicals or antioxidants,
all of that is really just describing the presence
or absence of charges that are bound or unbound.
So for instance, if you hear about free radicals,
sounds pretty wild, right?
Free radicals, what are free radicals?
Free radicals can damage cells.
They don't always damage cells,
but they can damage cells
because they are essentially free electrons.
They are a charge that's sitting out there,
not bound to anything,
and therefore can interact with the molecular structure of certain proteins
and change those structures by binding to them or interfering with the normal binding
processes of those proteins to water or to other things.
And in that way, cause damage to those proteins and potentially damage to cells.
Now, fortunately, our cells have ways to deal with those free radicals, and those are
called antioxidants. Now, fortunately, our cells have ways to deal with those free radicals, and those are called
antioxidants.
Antioxidants are molecules that can arrive in different forms.
Sometimes we think of antioxidants as vitamins, but they are also present in other things
as well, that essentially bind up those free radicals or repair the bonds between cells
so that the proteins are no longer undergoing these,
let's just call them bad confirmations that damage the functioning of our cells.
So there are many different theories of aging, there are many different theories of disease,
but there is not a single disease either of brain or body that doesn't in some way
involve the generation of what are called reactive oxygen species,
these free radicals and the damaging of cells at the level of their individual organelles
and so forth, nor is there a single disease of brain or body that has not been shown to benefit
from having some antioxidant interference get in the way of that oxidative process.
So, I realize today is pretty thick with nomenclature. For those of you that haven't already realized it, what you're
learning here is organic chemistry. So you can feel pretty good about the fact
that if you can understand the water molecule and understand a little bit about
what free electron is, which is basically a charge that's out there that can
potentially do damage and the interactions of things like reactive oxygen
species and the ability of things like reactive oxygen species
and the ability of stable bonds to buffer against
or repair certain damage to cells,
as we're describing it here,
well then what you're essentially thinking about
and what we're talking about is organic chemistry.
Now, since this is a discussion about chemistry
as a service to try and understand
the biological effects of water,
keep in mind that water itself,
believe it or not, can act as an antioxidant, provided that it's bonding to things in the
proper way, which requires that it get into cells in the proper amounts and rates, which
requires that the temperature and pH of that water be correct, and provided that there's
enough water there, and that that water isn't bound to
other things.
It's not containing solutes that are damaging and potentially that it's carrying some of
the good things such as sodium or that there's potassium present.
Again, the so-called electrolytes that allow cells to function well.
So that's a bit of a trench of information and I don't want people to get overwhelmed
or confused.
What I'm trying to do here is paint a picture
of the biology of water understanding
that when you ingest water drinking it down
or when you breathe water vapors in the steam room
or on a human day, that water is entering your system.
It's accessing your cells
through these two mechanisms, diffusion across cell membranes,
or movement through ocorporean channels,
and then once inside those cells,
it's able to interact with and change the confirmation
of different proteins and accelerate or slow down
different cell reactions.
Everything from normal metabolism to blood pressure
to damaged cells, depending on a number of different features
of that water, as well as what the cells happen to be doing
in any given moment.
So with that in mind, I'd like to turn our attention to how water, depending on its temperature,
its pH, how much we drink or how little we drink, when we drink that water, et cetera,
how that can impact the health, disease, and repair of different cells, tissues, and organs
of our body.
Let's talk about how much water or more generally speaking, how much fluid each and all of us
should drink each day and how much fluid to drink depending on our specific activities
and environment.
Now, this is perhaps the most commonly asked question when the topic of water comes up.
How much water do I need to drink?
The other thing that comes up is a question
which is can't we just follow our natural thirst?
That is can't we just pay attention to when we're thirsty
and then drink fluids?
And then that leads to the other question
which is does the color of our urine
provide any indication as to whether or not
we are under hydrated, over hydrated,
or hydrating correctly?
So let me answer each of these things one at a time.
And in the backdrop, I want to highlight the fact
that there are many, many, if not dozens,
hundreds of studies pointing to the fact
that when we are dehydrated, our brain doesn't function
as well and our body doesn't function as well.
So what I'm attempting to do in that statement
is throw a net around the enormous number
of studies that have shown that even a slight state of dehydration, even 2% dehydration,
can lead to a significant and meaningful impact that is a negative impact on our ability to,
for instance, carry out endurance type behaviors.
So our ability to run on a treadmill and stop at the point
where we feel like we can't continue is going to be negatively
impacted.
That is, we will be able to perform less work for less period
of time when we are even slightly dehydrated.
Likewise, our strength is reduced by even slight dehydration.
Likewise, our cognitive performance, including memory,
focus, creative thinking, flexible thinking
of different kinds, are all significantly impaired
when we are in states of dehydration.
Now, that raises an additional question
that deserves attention, which is,
how do we actually measure dehydration?
Now, you hear different things.
Like, if you pinch the skin on the top of your hand,
and it takes more than three seconds to lay down again flat, then you're dehydrated. You hear different things like if you pinch the skin on the top of your hand and it takes more than three seconds to lay down again flat than your dehydrate, you hear
that. You hear, okay, if you are to press on your fingernail and see a change in the color
of the tissue just below your fingernail, which indeed does happen, and it does not go
back to its original color within one to three seconds, then your dehydrate.
You hear things like this.
If your ankles are swollen when you're wearing socks, you take off the socks and you can see
the imprint of the socks on your lower limbs, that means you're dehydrated.
You hear this kind of stuff and you should probably be wondering, is any of that true?
To some extent, it is true, although it can vary quite a bit by how old you are, whether
or not your, the skin on the top of your hand tends to be looser or not, depending on whether how old you are, whether or not the skin on the top
your hand tends to be looser or not, depending on whether or not you're leaner or not.
So in other words, those are not absolutely objective measures of dehydration.
Now it is true that if normally you can pinch the skin on the top of your hand and it returns
to its normal flattened position within about one to two or three seconds and it does not
do that within five or more seconds.
There's a decent probability that you're a little bit
dehydrated that you need to ingest some fluid.
Or that if you press down on your nail
and you see the depression causes a transition
from kind of a pink color to a white color,
and then you release, and it doesn't go back to
its original pinkish color within a few seconds.
Well, then there's a chance that you're dehydrated. But again, these are not perfect measures of dehydration.
You may be surprised to learn and I was surprised to learn that most of the basis for these statements
like even a 2% dehydration state can lead to significant reductions in cognitive or physical performance are based on not
direct measures of hydration, but rather a measures of reductions in water intake, which is a different
thing, right? It's saying that ordinarily a person of a given body weight needs X amount of fluid
per day, and when they get even just 2% less than that amount of fluid, then their cognitive
and or physical performance is impaired, rather than focusing on dehydration of tissues.
Now, that might seem like a subtle distinction, but it's actually a meaningful distinction
when you think about it.
However, it's a meaningful distinction that we can leverage toward understanding how much
water or fluid we need to drink each day.
Now there we can really point to some solid numbers that believe it or not are fairly independent
of body weight.
Now I say independent of body weight, I'm referring to the amount of fluid that most healthy
adults need at rest, what do I mean by at rest?
I mean when not exercising and when not in extremely hot environment.
So I'm leaving aside you desert ultra marathoners or people that are doing any kind of movement
or living in environments that are very, very hot.
Here I'm mainly referring to people that live most of their daily life in indoor environments.
It could be air condition or not air condition, heated or not heated.
Well, we're trying to arrive at here are some numbers that can work across the board because,
of course, there are an infinite number of different conditions that each and all of you
are existing in. So I'm not going to attempt to give you a body weight by activity,
by environment, by humidity, formula calculation. In fact, no such calculation exists. However, there are formulas that can put you
into very stable frameworks. That is levels of water intake for periods of rest when you're not
exercising and for when you are exercising that will ensure that you are hydrating with the one
exception being if you are exercising or if you are living in
very, very hot conditions and you're not heat adapted to those conditions.
So what are those numbers?
In other words, what is the answer to the question of how much fluid do we need each day?
And here I'm referring to fluid.
I'm not distinguishing between water, caffeinated beverages, soda tea, and so on.
I'll discuss that in a moment. We can reasonably say that for every hour
that you are awake in the first 10 hours of your day,
this is important.
In the first 10 hours of your day,
you should consume on average eight ounces of fluid.
Now, for those of you that are using the metric system,
not ounces, eight ounces of fluid
is approximately 236 milliliters of water.
And for those of you that exist in the metric system and aren't used to thinking about ounces
and vice versa, just thinking about a typical can of soda in the United States, it's 12 ounces.
In Europe, sometimes a cans of soda are a little bit smaller. That's a whole discussion unto itself.
But eight ounces of fluid, that is 236, let's just say 240 milliliters, because we don't
need to be too precise here, a fluid on average every hour for the first 10 hours of your day,
which translates to an average of 80 ounces of fluid for the first 10 hours of your day.
Or 2,360 milliliters of water, in other words, approximately 2 liters of water plus a little
bit more for the first 10 hours of your day.
Now I want to be very clear that this does not mean that you need to ingest 8 ounces or 236
milliliters of fluid
on the hour, every hour for the first 10 hours of your day.
I'm certainly not saying that.
And in fact, most people are going to find that they're going to ingest water in boluses.
That is, they're going to have perhaps 16 ounces of water, 500 milliliters of water,
one portion of the day, and then maybe a couple hours of later, they'll drink some more
water, or some more coffee, or soda, or some other beverage, and another portion of the day and there may be a couple hours of later that they'll drink some more water or some more coffee or soda or some other beverage and another portion
of the day.
I do think, however, it's important for most of us to take a step back and ask ourselves
whether or not independent of any other activity or environmental conditions, whether or not
we are, in fact, ingesting 80 ounces or basically 2.4 liters of water for that 10 hours of the
day that spans from the time we wake up until 10 hours later.
Now why am I setting this 10 hour framework?
The reason I'm setting this 10 hour framework is that it turns out that your fluid requirements,
even just at rest, are vastly different in the
time from when you wake up until about 10 hours later, as compared to the later evening
and nighttime.
And here I'm referring to people that are not doing night shifts, but if you are requesting
a number of how much fluid to drink, independent of our needs for fluid for exercise, that's
going to be eight ounces of fluid or 240 milliliters of fluid
on average for every hour from the time we wake up until 10 hours later.
That's the simple formulation that should basically ensure that you're getting sufficient
baseline hydration for the cells and tissues of your body.
Now if you are engaging in exercise, whether or not it's endurance exercise or whether
or not it's resistance training exercise, you are going to need additional fluids in order
to maximize the effects of that exercise and to avoid dehydration.
And there too, we have some excellent numbers that we can look to, excellent because they
arrive from research.
And this is largely peeled from the episode that I did with Dr. Andy Galpin, Professor of
Kinesiology at Cal State Fullerton. We did a six episode series all about exercise, everything
from strength training, hypertrophy, endurance, nutrition, supplementation, recovery, everything
related to exercise. You can find all of that at HubermanLab.com. And one of the components
of those episodes that was discussed, but that some of you may have not heard, is that there is a
simple formula for how much fluid
to ingest on average. Keep in mind, this is on average when you're exercising. And I refer to
this as the so-called galpin equation. The galpin equation states that you should take your body weight
in pounds, divide that by 30, and that will give you the number of ounces of fluid
to ingest every 15 to 20 minutes on average while exercising.
Your body weight, in pounds, divided by 30 equals the number of ounces of fluid to consume
on average every 15 to 20 minutes.
When I say on average, what I mean is it is not the case that you need to stop every 15
or 20 minutes
and consume that volume of fluid.
You could sip it from moment to moment.
You could wait half an hour or an hour and then consume a larger bowl of fluid, a larger
amount, although it is recommended for performance sake that you sip or consume beverages fairly
consistently throughout your training.
One's ability to do that is going to depend on a number of things like gastric emptying time,
whether or not that particular exercise you're doing, whether or not it's running or jumping,
is compatible with ingesting fluid on a regular basis or whether or not you need to do it at
different intervals than every 15, 20 minutes, maybe it's every five minutes, maybe it's
every half hour, you have to adjust for you, but if you were to take the hour of
exercise or the half hour of exercise or the three hours of exercise and ask how
much fluid to ingest, it's going to be that galvan equation of body weight and
pounds divided by 30 equals the number of ounces for every 15 or 20 minutes.
And of course, I can already hear screaming from the back, what about for those of
us who follow the metric system?
And there, there's a simple translation of the Galpin equation, which is that you need approximately two milliliters of water per kilogram of body weight every 15 to 20 minutes.
Again, the Galpin equation converted into the metric system is going to be two milliliters of water per kilogram of body weight every 15 to 20 minutes on average.
I'm sure a number of you are asking whether or not hydration prior to exercise is also important.
It absolutely is. And if you follow the numbers that I talked about before,
approximately eight ounces or 240 milliliters of fluid intake per hour in the first 10 hours of
waking, that should establish a good baseline of hydration
heading into exercise, which then prompts the next question I often get, which is, is
the amount of water that needs to be consumed according to the Galapun equation during exercise
on top of or separate from that, that is, does it replace the amount of fluid that one
needs at a basic level that eight ounces or 240
milliliters. And there, the answer sort of goes both ways. I think if you're going to
exercise, then obviously follow the Galpon equation in some way. Again, you don't
need to be ultra specific about this. These are ballpark figures that will
ensure hydration. So we've set them a little bit higher, perhaps the needed to
ensure more hydration rather than less.
But basically the short answer is if you're exercising for about an hour, most people are exercising for an hour or two, probably not more than that.
Most of my workouts are certainly the resistance training workouts last about an hour.
Well, then you can replace the eight ounces or the 240 milliliters of water that's required at baseline with what you consume according to the Galpon equation
during that bout of exercise.
A common question is if you are exercising
in a heated environment, indoor outdoor,
or you are somebody who tends to sweat a lot.
And by the way, we can all get better at sweating
by sweating more, sweat is an adaptation.
So if you sit in the sauna more,
you're gonna get better at sweating.
If you exercise more, especially if you wear more layers or if you do it in hotter temperatures
or more humid temperatures, you're going to get better at sweating over time and sweating
as an adaptation that helps cool your body.
If you are sweating a lot or you're in heat, how much fluid should you ingest?
In general, I think it's safe to say that you may want to increase the values on the
galpon equation by about 50 to 100%.
So either increase by 50% or double those numbers if you're in a very hot environment or sweating
an awful lot. If you are sitting in the sauna, I highly recommend consuming at least eight ounces
and probably more like 16 ounces of fluid. So that translates again to about 240 or about 480. Let's just round up 500 milliliters of fluid
for every 20 to 30 minutes that you are in a hot sauna.
And then of course people ask, well, how hot?
And it, okay, that starts getting really detailed
and we can't distinguish between dry saunas
and wet saunas and again, too many variables.
But I would double your fluid intake
for that hot environment exercise or for that hot environment
saw on a sit.
Also if you are feeling dehydrated, what does feeling dehydrated mean?
That actually has a definition that we can get into a little bit later, but what we're
really talking about here is if you are feeling as if your throat is dry, you are quote, unquote
parched, where you're very thirsty.
Well, then there's absolutely no problem
with ingesting more fluids, 16 ounces of fluid,
or 500 million years of fluid per hour
while you're feeling parched.
My read of the literature is that thirst
is a reasonable guide for when we tend to be dehydrated.
However, it is the case that our thirst
doesn't really keep up with our body's level of dehydration.
And we know that based on some really nice studies up with our bodies level of dehydration.
And we know that based on some really nice studies that have explored the amount of fluid
intake compared to the amount of urination compared to the amount of physical output compared
to the environment that one happens to be in.
These are sort of older studies in the realm of physiology, but here's the basic rule
of thumb that's going to work for most people.
If you are feeling parched, consume fluids.
Ideally, you consume fluids that don't contain caffeine or other diuretics, diuretics,
being substances that cause the release, the urination of fluid from the body.
And or if you are consuming caffeine either prior to or after a bout of exercise or even
just at work or you work in an air condition or otherwise dry, cool or hot environment that you try and include
some sodium and ideally sodium potassium magnesium, the electrolytes in that
beverage. It could be a little pinch of sea salt with some lemon to adjust the
taste a little bit. It could be an electrolyte drink of element or some other
sort. There are a lot of different types out there. For most people drinking
pure water. And I realized that many people do just like the taste
of pure water, chances are you're going to have enough electrolytes, unless you're sweating
quite a bit or you're exercising quite a lot, and under conditions where you're consuming
very few carbohydrates, you're going to excrete more fluid.
If you're ingesting caffeine, whether or not it's from tea or coffee, I highly recommend
increasing your non-caffine
fluid intake about 2 to 1 for every volume of caffeine.
So in other words, if you have six ounces or eight ounces of coffee, you're going to want
12 to 16 ounces of fluid, ideally fluid with electrolytes or a little pinch of salt in
order to offset that dehydration.
So hopefully those will provide good rules of thumb for what people want to do when they're just moving
about their day.
Again, underscored by the fact that even slight levels
of dehydration can really impair our cognitive
and physical performance largely by creating fatigue,
but more often than not by creating brain fog.
I get so many questions about brain fog.
Why do I have brain fog?
Why do I have brain fog?
There is a vast literature showing that quality hydration,
meaning hydration that matches the demands of humidity
and output as described in the equations
that we went over a little bit before,
really can enhance clarity of focus and overall energy.
And we'll talk about why that is,
but I'll just allude to it a little bit here.
The reason why ingesting sufficient fluids
can enhance our ability to focus,
and in fact can reduce brain fog
and can increase physical vigor and output
is not mysterious to us.
We know that there are two mechanisms
by which fluid intake triggers elevated levels
of alertness, and it all has to do
with the so-called sympathetic arm
of the autonomic nervous system,
which is a real mouthful, but basically the sympathetic arm of the autonomic nervous system, which is a real mouthful.
But basically, the sympathetic arm of the autonomic nervous system, as many of you heard
me talk about before, is the aspect of your nervous system that makes you more alert.
Has nothing to do with emotional sympathy.
Has to do with a bunch of neurons in the middle of your spinal cord called the sympathetic
chain ganglia, and some other related neural networks in your body, as well as regions
of your brain, like the locus arulias that release things, like epinephrine and nor epinephrine and make you more
alert. And in a kind of magnificent arrangement, or I think magnificent
arrangement, when we have fluid in our gut and when our cells are well hydrated
and believe it or not, when our bladder contains fluid within it, there is an
elevation and activity
of the sympathetic nervous system by way of two pathways.
One is mechanical.
In fact, we have so-called stretch receptors in our bladder and in our gut.
These stretch receptors have fancy names like TRP, TRIP channels, as they're called, or
Pieszo, which are these stretch sensing channels.
This is the beautiful work of many laboratories,
but in particular, David Julius and Ardum Petapuchin.
David Julius is at UC San Francisco.
Ardum is at the Scripps Institute.
They've discovered a bunch of channels and cells
that sense things from cold to different mechanical pressure,
including expansion of tissues, so-called mechanosensation,
and basically what it all boils down to
is that when our bladder has some fluid in it,
when our stomach has some fluid in it,
and when our cells are sufficiently hydrated,
they send information about the mechanical presence
of that distension, even,
and here I'm not talking about being overly full,
full, chocoblock, full of fluid,
or your bladder feeling really really
full.
We'll talk about that in a moment.
But when we are sufficiently hydrated, there's a mechanical signature of that, which is
the expansion of our tissues because it has more fluid in it.
And there are chemical signals as well, which is the movement of water across those aquaport
and channels is actually understood at a biological level by ourselves.
And sends information to the areas
of the brain that are associated with so-called sympathetic arousal and makes us more alert.
This is actually what wakes us up in the middle of the night.
If we have consumed too much fluid prior to sleep and we need to urinate, we wake up.
This is a mechanism that is not adequately developed in babies and young children.
This is why babies, young children often will wet their bed.
And believe it or not, both humans and in dogs, our ability to control your nation voluntarily
is something that we actually learn.
Babies just pee in their diaper.
Dogs just pee on the floor until their house broken or until a child learns to hold on
to their urine until they go to the bathroom and the bathroom
or particularly appropriate location outdoors or otherwise.
The point is that hydration of the body is signal to the brain.
When we have enough fluid in the tissues of our body,
when we consumed enough fluid,
even if it hasn't already arrived to the cells
in tissues of our body,
that is signal to the brain in the form of alertness.
And that alertness is what translates to the cells and tissues of our body, that is signal to the brain in the form of alertness.
And that alertness is what translates to the enhanced cognitive abilities that we have
when we are well hydrated.
It's also what translates to our enhanced physical abilities when we are challenged with
physical tasks.
So when you look out on the landscape of all these studies that have shown impairments
in physical or cognitive performance under conditions of even slight dehydration.
That all makes sense because our cells need fluid and we need water, but it also prompts
the question of, well, does being well hydrated actually make our brain and body function better
in the context of physical and cognitive performance?
And indeed, the answer is yes.
Now earlier, we were talking about these equations that you can apply.
And again, I really want to emphasize that these equations were not meant to be
followed down to the decimal point.
They were really meant and are meant as crude, but sufficient guides for you to
make sure that you're getting enough hydration, depending on your levels of
activity and at rest.
If you recall, when we talked about those equations, I said, you need about
eight ounces or 240 milliliters of fluid per hour for the first 10 hours of your day after
waking. Now, why does it say for the first 10 hours? Well, it turns out that the filtration of
fluids from your body, which is accomplished, of course, by your kidneys and by way of your bladder
and the excretion of fluid out your retra,
so-called urination, is strongly, strongly circadian dependent, meaning the cells of your kidney
and the cells, even of your gut.
In fact, all the cells of your body, but especially the cells of your kidney, which filter the fluid
that comes into your body, and that makes certain hormones like vasopressin, which is anti-diuretic hormone.
All of that, functioning of the kidney,
is under strong regulation by so-called circadian clock genes.
Circadian clock genes are genes that are expressed
in every cell, but that in certain cells of the body,
very strongly impact whether or not that organ,
in this case, the kidney is going to be activated,
meaning functioning at a very
high level or at a reduced level.
We can make all of this very simple by simply stating what's contained in this beautiful
review that I'll provide a link to if you want to learn more called circadian rhythms in
the kidney.
Basically, what is known is that for the first 10 hours after waking, your kidney is filtering
fluid within your body at a very rapid rate. There are a number of different cell types that do that, but they are basically taking
that fluid, pulling out any contaminants using hormones such as antideuretic hormone, vasopressin,
to adjust whether or not you're going to hold on to fluid or release more fluid from your
body in the form of urine depending on the salt concentration, depending on how much fluid
you need,
your work output, the conditions you're in, all of that.
However, at about 10 hours after waking,
your kidney really starts to reduce its overall level
of functioning.
Now, that doesn't mean that your kidney cannot
filter fluid, 11 or 12 or 16 hours after waking,
but it becomes far less efficient at doing so.
And thank goodness it does,
because you do not want your kidney filtering fluid
at the same rate at midnight,
assuming you wake up at say seven or eight or nine a.m.,
that it was filtering fluid at 10 a.m.
In fact, we can say that if you want to reduce your nighttime
waking in order to urinate,
which is a common, common question and concern that many people have, how can I avoid waking
up in the middle of the night to urinate?
And there I say, it's perfectly normal to wake up once, maybe twice each night to urinate.
But if you want to reduce the number of times that you wake up in order to urinate across
the night, maybe even make that number zero times, you will greatly benefit by doing three things.
First of all, make sure that you're hydrating sufficiently during the daytime per the
equations that we talked about earlier.
That will ensure that you are not excessively thirsty in the evening and therefore consuming
a lot more fluid. Second and related to that first point is that you do want to reduce your fluid intake
at night, provided you hydrated sufficiently throughout the day.
And believe it or not, the rate at which fluid moves from your gut and into the cells and
tissues of your body and then from your bladder into urine is determined not just by the volume
of fluid you ingest, but also the rate at which you ingest that fluid.
And you might be thinking, that's crazy. That makes no sense at all, right? If I drink a ton of
fluid slowly, doesn't it still mean that I'm going to urinate a ton? Yes and no. It also stands
to reason that you might ask, if I ingest very little fluid, but I do it very fast,
is it going to be the case that I'm going to urinate it out very quickly? Well, yes and no.
The point is that the fluid filtration systems of your body that range from the gut to the bladder and include the kidney, of course
depend not just on the volume, but on the rate of
fluid that you ingest. Because of those mechanosensors that we talked about earlier,
if you gulp down a bunch of fluids, you are going to excrete those fluids more quickly than if you
sip them slowly. So here's what I recommend. Throughout the day when you're trying to get your
adequate yield of water or other beverages, feel free to gulp that fluid or sip it. I'm a gulper, not a sipper,
but many of you are going to be sippers, not gulpers. Consume fluid at the rate that feels right to you,
but feel comfortable gulping that fluid. However, in the evening, if you are somebody who has
challenges with waking up excessively in the middle of the night, reduce your fluid intake,
provided you've hydrated properly throughout the day.
And I suggest consuming no more than five maybe eight ounces of fluid between the time of
10 hours after waking and when you go to sleep.
Again, if you're very thirsty or you under hydrated, it's very hot, feel free to ingest
more fluid.
Please.
But most people will find that if they reduce their fluid intake to about five ounces or
less of fluid in that later part of the day after 10 hours of
having woken up and before sleep and they sip those beverages as opposed to gulping them that they will have fewer
bouts of waking up in the middle of the night to go to the restroom and
ideally zero. Let's talk about tap water and And here I have to take a deep breath,
not a deep gulp, but a deep breath,
because in researching tap water
and what's contained in tap water,
in different regions, not just in the US,
but around the world, I confess the picture
is a pretty scary one.
I want to be clear, I'm not somebody
who naturally orients towards fear
or conspiracy theories.
However, in researching tap water for this episode, by way of looking at the peer reviewed
research, meta-analysis reviews, specific research articles, or specific hypotheses were
tested, and in talking with experts in toxicology and so on, it's a pretty grim picture, frankly, when one looks at what's contained in most tap water
and whether or not the compounds that are contained in tap water are present in sufficient
concentrations to negatively impact our health. And the bad news is that much, if not, all tap water,
believe it or not, much if not, all tap water contains things that are bad for the biology
of ourselves.
There is a silver lining, however, and the silver lining is that very simple steps that
are very inexpensive can be used to adjust that tap water to make it not just safe to drink,
but that makes it perfectly fine to drink.
So that's the good news and we'll get to that in a moment.
If you are somebody who is interested in whether or not tap water contains things like endocrine disruptors, hormone disruptors that can negatively
impact reproductive health in males or females or both. It's a wonderful review, wonderful
because it's so thorough, although the news isn't great, it's very thorough, which is great,
which is entitled Endocrine disruptors in water and their effects on the reproductive system.
This is a review from 2020 that analyzes water from a bunch of different sources within
the world and essentially focuses on a few key components.
First of all, it focuses on the concentration of minerals that is magnesium and calcium
within water.
Many people don't realize this, but so-called hard water.
Sounds terrible, right?
But hard water is water that contains magnesium and calcium, which turns out to be a good thing. Some water contains more magnesium
and calcium. Other water contains less. They looked at the presence of magnesium and calcium,
because that is going to impact the pH of water. In general, the higher concentrations of magnesium
and calcium and water, the higher the pH. That is, the more alkaline
that water is, and the lower levels of magnesium and calcium, the more acidic or lower pH that water
tends to be. The other thing that this review addresses is the concentration of so-called DBPs,
dog, bulldog, porcupines, DBPs, which are disinfection byproducts contained in water.
So obviously local governments, the government wants your drinking water to be clean.
They don't want contaminants in it.
They don't want sewage in that water.
They don't want chemical contaminants that are going to make people immediately sick.
So they treat water, water treatment plants, treat water with disinfection products and
those disinfection products and those disinfection
products create things called disinfection by products.
And the presence of those DBPs or disinfectant byproducts can strongly impact the pH of water
by way of changing the concentrations of magnesium and calcium.
Put differently, I do believe that governments are trying to provide people with clean water,
but in doing so,
oftentimes, we'll introduce things to that water that are not good for us.
Now, it's very clear that D.B.P.'s can cause endocrine disruption in ways that are not good
for reproductive health.
I did a very long, in fact, four and a half hour episode on fertility and vitality.
That was male and female fertility, by the way, and vitality.
Again, you can find at HubermanLab.com that talks about all the biological processes involved
in the generation of healthy eggs and sperm and creating a healthy embryos, implantation
embryos and so forth.
It's very clear that D.B.P.'s have been shown to disrupt ovarian functions, spermata genesis
and fertility outcomes, even at concentrations of DBPs that are present
in drinking water that comes from the tap.
Now does that mean that you shouldn't drink tap water?
Well, the answer to that is a, it depends.
What does it depend on?
Well, it depends on several things.
First of all, I highly recommend that everybody go online and put in your zip code and ask
for a water analysis of water that comes out of the tap in that zip code.
This is something that is readily available online, at least to my knowledge and unfortunately,
there's no specific one site that I can send everyone to to get an in-depth analysis of the drinking water that comes out of your tap.
However, I highly recommend that you go online and put in your
zip code or municipal area code and figure out whether or not your water contains X amount of
DBPs or Y amount of DBPs. Now, of course, you're going to get a bunch of values back and unless
you're a toxicologist, I'm probably not going to know what those values mean. But what you're really looking for is whether or not there are high, low, or moderate levels
of fluoride in that drinking water.
Why do I say that?
Well, there are studies that show that the concentration of fluoride in drinking water
is a particular concern for the thyroid hormone system of the body.
Now, thyroid hormone has a lot of different roles in brain and body, and thyroid hormone system of the body. Now thyroid hormone has a lot of different roles in brain
and body, and thyroid hormone is very important for everything from metabolism to levels of energy.
When thyroid levels are disrupted or thyroid receptors are disrupted, it can lead to depression.
When thyroid hormones are optimized, it can lead to optimal mood. If there is such a thing, but in
other words, it helps keep your mood elevated.
It relates to everything from sleep to reproduction. Thyroid hormone is involved in many, many
things, including bone health and tissue health generally. So, especially every biological
process in your body is impacted by thyroid hormone. And there is a study that I'd like to
highlight, which was published in 2018, and the title of the study is Impact of Drinking
Water Fluoride on Human Thyroid Hormones. This was a case control study, so this is not an extensive analysis of many individuals.
However, what it shows is that fluoride negatively impacts thyroid stimulating hormone
and so called T3 levels, so you have thyroid hormone T3 and T4, even in the standard concentrations
that are present of, and here's an important number, 0.5 milligrams per liter.
Okay, so if you can get a hold of the fluoride concentrations
in your tap water and find out whether or not
the concentrations are at, below, or exceed,
0.5 milligrams per liter, what you will find is that,
even just 0.5 milligrams per liter of water can disrupt thyroid function.
And this is going to be a particular concern for people to have familial, so genetically related,
thyroid issues, or that are concerned with keeping your thyroid hormone levels healthy, which I
think is everybody. So I am telling you that you should try and get a hold of some data about the
water that comes out of your tap if you intend on drinking tap water. And probably even if you don't, just know what's in your drinking water.
Your local government should provide that information and or it should be readily available online.
And in particular, I think it's worthwhile to address how much fluoride is present in
your drinking water.
Again, I don't want to create a lot of scare.
I'm not trying to trigger fear here.
I do think, however, by way of reading
this review, by way of reading the paper that I just referred to a moment ago, again, links to these
are going to be provided in the show note captions, that there is extensive evidence that elevated
levels of fluoride and drinking water are simply not good for us. Now, that could open a whole
discussion of why fluoride is in our drinking water in the first place at all, but leaving that aside, it seems to me that most everybody should know
how much Florida is in their drinking water.
And ideally, everybody, yes, everybody is filtering their drinking water.
Now, that raises the question of how best to filter drinking water.
And that brings an answer of, it depends on a couple of things.
First of all, how healthy or unhealthy do you know yourself to be? Okay? So if you're
somebody who has no health issues, you're planning a vigor, you're sleeping well at nights,
you have no autoimmune disease, you're not aware of any health concern, minor or major,
well then perhaps you're somebody that doesn't want to filter your water. I would argue that why wouldn't you employ some very low or even zero cost approach to filtering your water? There are going to be other individuals
who are suffering particular ailments of brain or body or both that absolutely should
be filtering their drinking water if they're getting their drinking the water from their
tap because it is pretty well established now that tap water contains a lot of these disinfectant byproducts as well as in most cases exceeding the threshold
of fluoride that we know to be healthy for us.
How should you filter your tap water?
Well, you have everything ranging from the so-called Brita type filters.
So these are going to be carbon type filters or other filters that you essentially put over
a container or a compartment where you can pour the water over it and goes into the compartment
below.
Will those work?
Are they sufficient to filter out the disinfectant byproducts?
The general answer is yes provided you change the filters often enough.
However, it is not thought, unfortunately not thought that they filter out sufficient
fluoride.
So what I highly recommend is depending on your budget, that you go online and you search
for at-home water filters that can filter out fluoride.
There are a number of straightforward and inexpensive tools to do that.
And here I don't have any relationship to any of the water filters or things that I'm
going to mention now.
I want to be very clear about that.
There's no brand coder affiliation here.
I'm simply trying to direct you to resources that will allow you to filter your tap water
for it to be more safe for you to consume in a way that meets your budget with the understanding
that people have very different disposable incomes.
So the range of costs here is going to be pretty tremendous.
I just want to get that out of the way for a say.
You know, there are water filters that you can use repeatedly.
So these are what I'll refer to as picture filters
that are less than $100.
Now keep in mind that that's a one time purchase
except for the replacement of the filters,
which fortunately doesn't have to be done too often.
So there are different filters.
I'll provide a link to one that I found
that is at least by my read of the lowest possible cost.
So this is the so-called clearly filtered water pitcher with a finity filtration. So this is a filter that can adequately
remove fluoride, lead, BPAs, glyphosate, hormones, and some of the other harmful things that
are contained in most tap water. Again, I do realize that for some people, even in 80 US
dollar cost is going to be prohibitive, but do realize that what you're doing here is you're purchasing a unit that can be used repeatedly over and over
The reason why it's lower cost than some of the different filtration approaches that I'll talk about in a moment are that you can't really put
All the drinking water that you would use say for an entire week or for an entire month in one picture
You're going to have to repeatedly pour water into the pitcher in order to filter it.
Now, as I mentioned before,
the range on water filter costs for filters
that can adequately remove fluoride
and all the other things that you want out of your top water
is immense.
In fact, you can find whole house water filters
that are $2,000 or more.
Again, these are gonna be filters that are gonna be
in your garage or in a laundry room
that are going to basically pull from the piping system
of your house and deliver purified water.
Technically, it's not purified,
but that's removing these contaminants and fluoride
from all the sinks in your house
so you can effectively drink from any
or all things in your house.
That's what explains the higher cost.
I think most people are probably not going to have
the disposable income or have the opportunity
to include one of these whole house filters,
although if you do have the means and it's important to,
you could do that.
And then there are going to be what I would call
intermediate systems.
So systems that cost somewhere between $200 and $500,
probably one of the more common ones or popular ones
is a so-called burky filter system.
These are filter systems that again remove the things that you want removed from your tap
water and they can do it at higher volumes and they're typically counter top units.
They don't require any plug-in typically or they only require brief plug-in and electricity
and they're going to filter out many, many liters or tens of liters of water so that you
can always have access to that clean filtered water at any time or day or night
without having to pour over into the picture.
So I mentioned these different options
because again, I realize that people have different levels
of disposable income.
As far as I know, there's no tablet or simple mechanism
that can be purchased as a transportable,
pill that you can just simply throw in water and remove the contaminants. If anyone is aware of one that can be purchased as a transportable, you know, pill that you can just simply throw in water
and remove the contaminants.
If anyone is aware of one that can adequately remove fluoride
and other contaminants, please put in the comment section
on YouTube, that'd be the best place
so that I and everyone else can see it.
But hopefully the mention of the different filtration systems
that I mentioned will give you some choices that I would hope
would fall within the range that
one could potentially afford. An important note about filtration. Just as in our body, there
are mechanisms to signal mechanical changes and chemical changes that occur in our gut in
our brain, et cetera, elsewhere. And in general, both mechanical and chemical changes are
signaled across the body to invoke different changes, whether or not those are a response of the immune system or to make us more alert or more asleep,
et cetera.
So too, filtration capitalizes on mechanical and chemical filtration.
What I mean by that is when you run a fluid water or any other fluid through a filter, those
filters are doing two things. They are physically constraining which molecules can go
through by creating portals, pores that allow certain size molecules to go through and not others,
and almost always they contain certain chemicals themselves, right? Those filters have been treated
with certain chemicals that neutralize certain other chemicals. Okay, so you may be wondering how when you filter water, you know, magnesium and calcium
could get through, but fluoride doesn't.
And that's because these filters have been very cleverly designed in order to neutralize
fluoride or to prevent large molecules such as sediment and dirt, which is kind of easy
to imagine being filtered, but also to allow certain small molecules,
like calcium, which is small ish, or magnesium, which is small ish, to still pass through
into our drinking water.
And this is wonderful because what it means is that by filtering our water using any of
the methods that we talked about before, you're still going to get whatever magnesium and
calcium was present in that water while still adequately removing the fluoride and other
disinfectant byproducts. Now what if you can't afford any of those options?
Okay, well, here you have an interesting zero cost option.
It's not as good as the other ones of filtering that water, but it is an option.
And I do think it's important to give options to people who don't have any disposable income
for the purpose of filtering their water, which is to draw a gallon or five gallons
or maybe even more tap water out of the tap
and put it into some container, some vessel,
so it could be one gallon, five gallon,
10 gallon container, and then to let that tap water
sit for some period of time to allow
some of the sediment to drop to the bottom.
Now you might say, well, there's no sediment,
there's nothing contained in that tap water and it isn't fluoride diluted in the water. And indeed, the answer
to that is yes. However, there is some evidence that letting tap water sit out at room temperature
and outside the pipes that deliver that water can help remove some, not all, of the contaminants
in that water. If however you are filtering the water using any of the methods that I talked
about a few moments ago, you do not need to do this.
Okay, I realize there's a whole world out there of people who insist on putting their water
in the sun or only keeping it in certain containers and putting it out for a few days
before they get interested.
That to me seems a bit extreme, if you want to do that, be my guest, but I don't think
most people need to do that.
However, I do believe that for people who have zero disposable income to devote to
paying for any kind of filtration system for their tap water, they're taking that tap water
and putting into some container at room temperature and keeping it room temperature for a half
day or a day or more, and then pouring off the top two thirds of that water into another
container and consuming the water from that second container is going to remove some, not all of the contaminants
that one would need to be concerned about.
And here I should mention something
that I neglected to mention a few moments ago.
If you were going to do this zero cost option
and let the water sit out for a bit,
you would want that water to sit uncapped.
Sorry, I should have mentioned that before, uncapped.
Of course, trying to keep things from falling into that water.
In fact, you could even put a little bit of cloth above it.
So you don't want things falling into that water,
but you want certain things to be able to evaporate off.
And you also want some of the sediment to drop down.
And the reason why this process of letting water sit out
would work at all is because many of the contaminants
contained within water are not present because of the source of that water, or even the treatment of that water, but rather because of the pipes
that that water arrives to your glass or the pot that you have from.
Okay, and here again, there's an infinite number of variables.
So some people are living in buildings for which the pipes are very, very old, but very,
very clean, believe it or not. Some people are living in newer buildings and structures that have new pipes, but for
which the seals between those pipes contain things that are not good for you to consume.
So by letting water sit out for a while, you're able to remove some of the contaminants present
within the pipes of your home and the building and even the pipes that lead to your home or apartment.
Some people get really obsessed with this old tap water thing and really want to find out
all the details about the pipes and what sorts of hard metals and how much magnesium and
how much calcium or present in their water.
There are ways that you can test your drinking water for those sorts of things.
Most people I realize, including myself, are simply not going to do that.
If you want to know what I do, I tend to drink water that is filtered through one of these
lower cost filters.
If I'm going to be consuming a lot of fluid, I will drink certain kinds of fluid that later
I'll tell you, I've been doing an experiment for a sake of this episode, looking at so
called molecular hydrogen water, which sounds very fancy and esoteric and almost a little
wacky, but it turns out it has largely a deal with the amount of magnesium
and calcium in the pH of that water.
So if you are somebody who has a very low budget
or simply just wants to spend a very small amount of money
and trying to still drink tap water,
there is absolutely a way to do that safely,
but it does require a few of these steps.
So on the topic of magnesium and calcium,
this relates, as I mentioned earlier, to the
quote unquote, hardness of water. So what of the hardness of water? You know, is it better to
have more magnesium and calcium in your water or less? Some people don't like the taste of hard water.
They prefer the taste of water that has less magnesium and calcium. However,
there I would encourage you to take a step back and consider some of the literature. In fact, I'll mention a paper in particular now published in
2019, which describes the quote, regulations for calcium magnesium or hardness and drinking
water in the European Union member states. Turns out in Europe, they do very detailed
water analysis, and that's present in a number of really high quality scientific publications.
This was a paper published in regulatory toxicology and pharmacology, and they cite a number of really high-quality scientific publications. This was a paper published in regulatory toxicology
and pharmacology, and they cite a number of different references
in the introduction that, for instance, in here,
I'm quoting statistically significant inverse association
between magnesium and cardiovascular mortality.
Now, again, that's an association.
This is not causal, but higher magnesium in water,
lower cardiovascular mortality.
They go on to say the highest exposure category, which are people consuming drinking water
with magnesium contents of 8.3 to 19.4 milligrams per liter.
Again, when you get your water analysis, you can compare against some of these values.
What's significantly associated with decreased likelihood of cardiovascular mortality by 25% compared
with people consuming magnesium content of 2.5 to 8.2 milligrams per liter.
Okay, so what this basically shows, and by the way,
the reference to that, I'll also provide a link to in the show note caption.
What this basically states is that higher magnesium containing water,
and it turns out higher magnesium and
calcium in containing water, so called harder water, may not taste as good to you, but
turns out to be better for you.
Now whether or not it can prevent you from getting cardiovascular disease, I don't know.
In fact, I would probably just state no.
It probably won't prevent you from cardiovascular disease.
You still need to do all the other things that are important for avoiding cardiovascular disease
and cerebral vascular disease.
For that and what to do in order to avoid cardiovascular disease, I strongly encourage
you to listen to the episode with Dr. Peter Atea that's coming out in a few weeks that
gets deep into that topic and the actionable items for avoiding cardiovascular disease.
But basically, as this study quotes, there is a growing consensus among epidemiologists
and epidemiological evidence, along with clinical and nutritional evidence,
that's strong enough to suggest that new guidance should be issued in terms of how these different
sources of tap water should enhance, not deplete, the amount of magnesium and calcium in that water.
Now, this ought to raise a very important question in all of your minds, which is, why is it
that magnesium and calcium concentrations are relevant to cardiovascular diseases?
Is it something about what magnesium does in cells or what calcium does in cells?
Are we all magnesium and calcium deficient?
Well, it turns out that's not the case.
The major effect by which magnesium and calcium in water are likely to impact things like blood pressure, cardiovascular
disease, and other aspects of cellular function.
Turn out to be somewhat cryptic, but we can make that cryptic aspect very clear by saying
that when we have more magnesium in particular, but also calcium present in our water, so
called hard water, you increase the amount of hydrogen
in that water, it becomes what we call hydrogen rich, and the pH of that water is increased.
Now, again, this does not mean that we are trying to change the pH of the cells of our body
in any kind of meaningful way. In fact, we don't want to do that. We want the pH of the cells of our
body to stay in particular ranges, as I mentioned earlier, but having more
magnesium and more calcium in our water, that is increasing the hardness of our water,
changes the pH of that water and it turns out that the elevated pH of water, that is,
pH of water that tends to be somewhere between high sevens, so we could say 7.9 up to even 9 or 9.2 is going to be more readily absorbed and is going
to more favorably impact the function of ourselves than lower pH water.
Again, I want to restate this because I'm a little bit concerned that maybe a clip of
this is going to be taken and send elsewhere and someone will get the impression that I'm
saying that we actually want to drink high pH water
that we all need to buy expensive high pH water.
Turns out that's not the case.
If you're consuming tap water from a location
where levels of a magnesium are sufficiently high
in that tap water again, where the level of magnesium
is 8.3 to 19.4 milligrams per liter of water,
that is if the water coming out of your tap is
hard enough, well then chances are you don't need to enhance the pH of that water change its
magnesium concentration. If however the water that you're drinking from the tap filtered or not,
I would hope filtered, contains less than 8.3 milligrams per liter of magnesium. Well then chances are the pH of that water is
going to be low enough that
It's not going to be lending itself to some of the favorable health
components that higher pH water can notice. I did not say that lower pH
Aka more acidic water is bad for you. I didn't say that. I said that higher pH water can be good for you.
So let's talk about how and why higher pH water
can be good for you and some of the best
and in fact very inexpensive sources
of higher pH magnesium enhanced
or simply tap water that contains sufficient magnesium
can be used and accessed.
Many of you are probably wondering whether or not
you can simply boil your tap water
and thereby decontaminate the tap water.
There I want to caution you,
it turns out that some of the contaminants present in water
are actually made worse by heating water.
And again, I don't want to open up a whole catalog
of different fears.
I like all of you, I presume, use water to cook, pasta rice,
because I'm an omnivore, I do consume those things.
I confess if I make your bommatte or any kind of tea or coffee,
I tend to use a higher quality water source than tap water,
even if that tap water is filtered,
because I like the taste far more if I use a really good source of water.
And again, because I'm not consuming those beverages in enormous volumes, that becomes a relatively inexpensive
endeavor.
But I would caution people against using boiling
or heating of water as the only method
to decontaminate their tap water and instead
to also rely on some of the filtration systems
that I talked about before.
And as long as we're talking about the temperature of water,
there is sort of an ongoing debate online.
It's not a huge debate, but a number of people engage in this debate as to whether or not
drinking really cold water or room temperature water is better for you or worse for you.
This is a tough one to resolve.
It turns out that if water is very, very cold, that is if you drink it and you can feel that cold water
making its way down to your gut and you can actually feel it as cold within your gut, and that's
sort of a, you know, back of the envelope, or I should say direct within the gut measure of
cold versus body temperature water, that it is going to be slower to absorb, that is you're
going to feel it sloshing around in your stomach for a bit longer.
Then if you were to consume water that is slightly warmer.
Now, that is not to say that you should ingest warm water
or room temperature water.
However, many people find that when they drink very cold water
or ice water, that indeed it can alter the kind of sensation
of the lining of their stomach in ways that, at least least to them feel like it's altering their digestion.
And that makes sense. The cells that line the gut are very temperature sensitive. You want this.
So for a number of reasons, including not consuming food that is excessively hot or cold or damaging your gut.
But in general, most people know the temperature of fluid that they want to ingest and ingest that temperature of fluid.
So most people, for instance, on a cold day, want a warmer hot fluid.
Does that mean that you're not going to absorb that warmer hot fluid?
No, of course it doesn't. You're going to absorb that fluid one way or the other.
So drink fluids at the temperatures that are to your liking in that moment.
In other words, what you desire in that moment.
And don't worry so much about trying to avoid cold beverages
or trying to make sure that you're always consuming
room temperature water as opposed to cold water.
So now with your understanding of hard water,
soft water magnesium, the relationship between magnesium,
calcium and the pH of water,
and remember our earlier conversation
where we talked about how higher pH water
is actually going to move out of the gut
and into the body a bit more readily. across those aquaporin channels more readily than lower pH more
acidic water. Well that raises the question of whether or not all these
different forms of water that are out there reverse osmosis water distilled
water double distilled water deuterium depleted water alkaline water as it's
often called whether or not any or all of that has
meaningful health outcomes.
Here we can address some of those items pretty quickly.
For instance, distilled water and double distilled water is essentially distilled of, that is
it has magnesium and calcium removed from it.
So my recommendation would be to not drink distilled water.
There may be specific circumstances
where somebody has very high levels of blood magnesium
or calcium or calcium stores within the body
that would necessitate them drinking only distilled water,
but that seems like a very isolated kind of niche case.
So in general, consuming distilled water
is just simply not necessary.
Now in terms of reverse osmosis water, what is reverse osmosis water?
Reverse osmosis water is water that has been passed repeatedly through a series of filters
that are designed to remove the kinds of contaminants we were talking about earlier.
So, some of the basic contaminants like disinfectant byproducts, fluoride, and some other large and small molecules that leaves
the water ideally still containing magnesium and calcium, although there's some evidence that
reverse osmosis water can deprive water of some of the magnesium and calcium. So if you are going
to use reverse osmosis filters and drink reverse osmosis water, you want to make sure that you're still
getting the magnesium concentrations present in that water that we talked about earlier.
But in general, reverse osmosis water is considered safe, but, and for many people this is going
to be an important but, but very expensive to access.
The reverse osmosis filters require a lot of changing of the filters, purchasing reverse
osmosis water in its stable form within containers.
These are typically last containers.
It's going to be pretty expensive and prohibitive for most people. is the osmosis water in its stable form within containers. These are typically last containers.
It's going to be pretty expensive
and prohibitive for most people.
That said, there are a number of people out there
that really like the taste of reverse osmosis water.
They report it as feeling more smooth.
They think of reverse osmosis water as quote-unquote
giving them energy to be quite honest.
There's no direct studies of the subjective sensation of water in the mouth and in the gut
and its relative health effects.
Again, the smoothness of water as one drinks it and goes down the gut really has no direct
relationship to the, quote, unquote, hardness or softness of water.
I know that's going to shock a number of you.
You probably think, well, hard water is going to be hard to drink. And it turns out that's not the
case. In fact, many people find that with elevated levels of magnesium and calcium in water, it actually
tastes smoother or softer in their mouth. So hard water tastes smooth or soft. I know it's all very
counterintuitive, but I think it's important to point this out because a number of times you'll
hear or read about filtering water so that it tastes smoother and better and oftentimes that's
happening because the, quote unquote, hardness of water, that is the concentrations of magnesium
and calcium are actually increasing.
So if you're somebody who's curious about reverse osmosis water and you can afford the filters
or the reverse osmosis water already pre-filtered, please be my guest.
You know, drink it. I'm certainly not trying to prevent anyone from drinking it. But
there's no pure review evidence that I am aware of that conclusively shows that
drinking a reverse osmosis water is far better for us than drinking other types
of water provided the other types of water are adequately filtered of fluoride
and the sorts of disinfectant byproducts that we talked about earlier. So what
about hydrogen water? You may have heard of this, or hydrogen in rich water, or electrolyze reduced water as a
way to access hydrogen in rich water.
All this might sound pretty crazy to some of you.
Now, fortunately for sake of today's discussion, we can take a number of the different categories
of, let's call it, unique categories of water that have been described,
including deuterium depleted water. And by the way, deuterium is something that relates to the
presence of hydrogen ions in water and put very simply water that is extracted from sources that
are closer to sea level, tend to have more deuterium in them than water that is extracted from sources
further from sea level. So up in the mountains, water that is extracted from sources further from sea level.
So up in the mountains, for instance, and from springs further away from oceans.
As you get closer to sea level, the sources of water separate from sea water tend to have
more deuterium, which relates to the enrichment or lack of hydrogen within that water, or free
hydrogen within that water.
I warned you, this was all going to sound pretty niche
and that we were going to get a little bit into the chemistry,
but now I'm going to make it all very simple for you,
at least for the non-efficientado.
Electralyzed reduced water, which is a method of using electricity
to alter the confirmation of the water molecules
and their rates of movement as well,
as well as so-called hydrogen-rich water, or hydrogen-enriched water, or deuterium-depleted water,
all have the property of having higher levels of pH than other forms of water, such as distilled water,
reverse osmosis water, and generally higher pH than
the kind of water that comes out of your tap, unless you live in a region where your tap
water has very high levels of magnesium in it, which does occur in certain regions of
the world, but is not that common.
More typically, the water that comes out of your tap does not have enough magnesium, meaning
not as much magnesium in it as you would like.
And this I believe explains in a fairly straightforward way why there is such an appeal of these
pH enhanced or alkaline waters or electrolyze reduced water or deuterium depleted water.
There are a couple of reasons, but first of all, anytime someone is consuming a specialized
form of water, chances are it's going to be filtered of the disinfect but first of all, anytime someone is consuming a specialized form of water,
chances are it's going to be filtered of
the disinfectant byproducts, fluoride,
and the other things that you really don't want in water.
So already the water is going to be cleaner
than would be coming out of the tap.
So that's going to indirectly explain
a number of the so-called health benefits,
both subjective and perhaps even objective,
as we'll talk about, that can result
from consuming these other, let's say, more esoteric forms of water,
at least not of simple tap water.
However, if you look at hydrogen or hydrogen in rich water,
you really need to take a step back and ask,
what is that?
You know, what are we really talking about?
Because it turns out that you can create hydrogen
in rich water by putting tablets
of magnesium itself. Small amounts of magnesium dissolving those in water, it will give off a kind
of gaseous solution. You'll see a bunch of bubbling in there. You certainly want to dilute that
tablet and then consume the water. And yes, it's true what you've heard about in red from these
commercial sources. You do want to consume that water within about five to 15 minutes
after that tablet completes dissolving.
Now, why would you do this?
I should say that I have now started doing this,
not because I necessarily think that it's so necessary or so beneficial.
I'll talk about my experience in a moment.
I did it in anticipation of this episode because I was researching water
and hydrogen and rich water and all these alkaline waters. And what became very clear to me,
based on reading a fantastic two-part review. It's a very extensive review entitled, at least the first
part is entitled, Electralized Reduced Water. Molecular hydrogen is the exclusive agent responsible for
the therapeutic effects. And then there's a second part to this review. This is how extensive is entitled,
Electrolyze Reduced Water,
number two, Safety Concerns and Effectiveness
as a source of hydrogen water.
What this review, which we've linked to in the show notes,
points to is that all of the health benefits
of these different forms of water
that you hear about out there,
deuterium depleted, hydrogen enriched, et cetera,
all seem to boil down, no pun intended,
no boiling included, I should say,
to the elevation in hydrogen that translates into,
and here's the really meaningful change,
the elevation in pH that occurs when you hydrogen
in rich water.
Now, there are not a lot of clinical studies looking at hydrogen in rich water,
but they're starting to be more than a few. And one that I'd like to point out and that will link to
was published fairly recently, which is entitled Hydrogen Rich Water Reduces Inflammatory
Responses and Prevents Apotosis. Apotosis is naturally occurring cell death during development and is
generally used to describe cell death of the body. Sometimes this can be good cell death during development and is generally used to describe
cell death of the body.
Sometimes this can be good cell death, by the way, removing cells that need to be removed.
Again, the title of the paper is Hydrogen Rich Water Reduces Inflammatory Responses and
Prevents Apotosis of Peripheral Blood Cells and Healthy Adults.
It randomizes double-blind control trial.
Now this paper looked at the effects of drinking 1.5 liters per day of hydrogen in rich water
for a period of four weeks.
They did find significant positive benefits of reduced inflammation, and they found these
changes by way of analyzing things like interleukin 6 and some of the other interleukins, which
are markers of inflammation. They controlled very nicely for the fact that people were still consuming other forms of water
and liquid and coffee, etc. Although they made sure that they weren't consuming too much coffee
and soda in addition to this hydrogen enriched water. But what this paper shows is that indeed
increasing the free hydrogen and water can improve certain health metrics in these cells.
And this is in keeping with some of the subjective reports
that people have stated out there,
and that I myself experience,
I have to say that by drinking hydrogen rich water,
which I'll tell you how to do fairly inexpensively in a moment,
you do get the subjective experience of having more energy, of feeling better."
Quote unquote.
Now keep in mind, of course, the placebo effect
is a very real and powerful effect.
So it could just be placebo.
Although in this paper, they did, of course,
include a placebo group.
So people didn't know if they were getting hydrogen
which rich water or non-hydrogen rich water.
I should also mention that the improvements
in health metrics
that they observed in this study were only observed
for individuals older than 30 years old.
Why that is, I don't know.
The conclusions these authors came to in terms of
how these individuals older than 30 achieved lower levels,
where I should say reduced levels of inflammation
and improved markers of other aspects of biological function
is that the hydrogen water improved
the biological antioxidant potential of certain cell types
and again, the cell types that they mainly focus on
were these peripheral blood cells in this particular study.
Now, how could this be?
Why would this be?
Well, this goes back to our earlier discussion
about reduction in
reactive oxygen species, so-called ROSs and
reductions in free radicals that can damage cells. So if all of this is sounding very convoluted,
I can understand why. However, what I like about this study and the two reviews that I mentioned a moment ago is that these studies don't really say that hydrogen-rich water is what's
essential.
What these studies really point to is that the changes in pH of water that enhancing the
hydrogen in water can create is what leads to the enhanced either absorption and or ability
of cells to utilize that higher pH water, again, not by changing the pH of the body or of cells,
but simply because higher pH water, or we could perhaps more accurately state, less acidic water,
that is, harder water that contains more magnesium and calcium, seems to be more readily used by the cells of the body, and therefore it's very likely that the individuals in this study
were achieving higher or more efficient levels of hydration.
So if any of this is confusing, let me be very clear.
I do not believe that we all need to drink deuterium depleted water, or that we all need to drink
electrolyzed reduced water, nor do I necessarily believe that we all need to drink hydrogen rich water.
However, it's very clear to me that all these different forms of water
are better absorbed and therefore lead to better and more efficient hydration
and therefore can reduce inflammation, blood pressure, and improve a number of other health metrics.
Because of the elevated pH that all of these different purification or water treatment
methods achieve, and that elevated pH, again, is not changing the pH of the cells and tissues
in organs of your body.
You actually don't want that.
Rather, that elevated pH is simply making the water less acidic than it would be otherwise.
So the simple takeaway is this, if your tap water contains sufficient magnesium per the
values that we talked about earlier, I don't think you need to hydrogen and richer water.
I do, however, suggest that you at least analyze your water or look at some of the professional
analysis of water that you can achieve online and
filter out disinfectant byproducts and fluorides, etc. from that
magnesium where I should say sufficiently magnesium containing water, okay? Put simply if your tap water has enough magnesium filter it but drink it and I think you're doing just fine if
however the levels of magnesium in your tap water are not
above that value that we
talked about earlier, in that case, I do think, and I can completely understand why, enriching
the amount of hydrogen in that water can make that water not only more palatable, right,
give you the sensation that it's softer or smoother or more enjoyable to drink, then more acidic water
would be, but also that that water is going to be far more effective in being absorbed
and hydrating the cells and tissues of your body which turns out to be very important for
an enormous range, perhaps every biological function within your brain and body.
So how can you hydrogen enrich your water?
That actually can be done fairly inexpensively.
I've been doing that, as I mentioned earlier, as part of an experiment in preparation for this episode,
because it turns out that the water that comes out of my tap has very little magnesium in it
and very little calcium as well.
The way to create hydrogen-rich water is you can simply purchase molecular hydrogen tablets,
which in reality are just magnesium tablets that dissolve in water and create a free hydrogen that can interact
with the other water molecules.
Now the chemistry behind it has been substantiated and I'll provide a link in the show note captions
to a paper that gets into some fairly extensive detail about the way that having an additional
hydrogen in your water can adjust the flow
of electrons and the adjustment of free radicals.
But keep in mind, again, this is all through increases in the pH of your water.
And please keep in mind that you can't simply take any other or any old magnesium tablet
or capsule and put it into water.
The configuration of the magnesium in these capsules and tablets is such that it
allows a rapid dissolving of the tablet and the activation of the free hydrogen that can
interact with the water molecules. Again, there are only a few scientific studies exploring
the real biological effects of these activated hydrogen waters. The dissolvable tablets are the far less expensive way to go than purchasing pre-packaged
and sealed hydrogen water. In fact, I don't recommend those brands because they are quite expensive
and it's not clear how stable the activated or free hydrogen is in those waters. In any case,
this is certainly not something that everyone needs to do. I mention it because I have had a good experience with it myself.
I also will mention again that I have no business or affiliation to any of these products.
I'll provide a link to a few of them in the show note captions for those of you that want to experiment.
And indeed, that's why I'm telling you this.
For those of you that want to experiment with raising the pH of your water
without having to purchase what is ordinarily quite expensive,
higher pH water. You can do this with these dissolvable magnesium tablets. My experience with them
has been quite good. In fact, I plan to continue to use them once or twice a day. This is not the
sort of thing that you need to do in all the water that you drink. I want to repeat, even if you go
down this path and you find that you really like the activated hydrogen tablet approach,
it is not the case that you want to put these in all of your water and you certainly don't want to put them in
carbonated waters of any kind that will lead to a lot of gastric discomfort
nor do you want to put them into hot liquids of any kind. So again, this is the sort of thing that you do once or twice
maybe three times a day and you can find out for yourself and measure
subjectively whether or not you like the experience and whether or not you, quote unquote,
feel better.
Now earlier in the episode, we were discussing structured water or this fourth phase of
water.
I know a number of people out there are curious as to whether or not ingesting structured
water is somehow better for us than ingesting non-structured water.
All I can say about this is that it is a very controversial thing to suggest that structured
water is somehow more biologically effective or better for us than non-structured water.
There are a number of different ways that one can create structured water.
They involve some pretty extensive and expensive at-home systems ranging anywhere from a couple of hundred dollars to
a couple of thousand dollars or more to be quite direct when one goes into the
peer-reviewed scientific literature. One will not find that is there is essentially
no real evidence that ingesting structured water leads to any specific
desired biological outcomes.
As I say that, I'm sure there are people out there who have still had tremendous experiences
ingesting structured water, whether or not that's due to a placebo effect or a real effective
ingesting structured water, is clear.
Just to give you a sense of what my stance is on things like structured water, I think
that they are interesting and intriguing, but as a scientist in the absence of any quality peer
review data at present, I can't really suggest that people go out and start ingesting structured
water nor that they adhere to the claims that structured water is going to be really, really
good for them compared to other forms of water. That said, I do think that there's an interesting and open space for further exploration of the biological effects of structured water, given
the fact that structured water does exist, I don't think anyone debates that, and the
fact that the different structures of water in this fourth phase of water, as we're calling
it, has been shown to interface with solids and other aspects of liquids and can do so within organelles of cells.
So different components of cells that control different functions, including mitochondria.
I think there's a potential there, whether or not there's a promise there is another
question entirely.
So I don't want to shut the door on structured water.
I think this is an open question that I hope there will be more data to answer those questions in the not too distant future.
And meanwhile, if any of you are aware
of good clinical studies exploring the biological effects
of structured water in either animal models or humans,
please put those references in the comments on YouTube
because I'm very curious as to how this area
of biological effects of structured water
is evolving and continues to evolve.
So today we discussed water.
And admittedly, we went into a lot of detail
about the physics and chemistry of water in its various forms.
And we talked about hydration,
because I think that's the main reason why
many of you are interested in or concerned about water.
We also talked about contaminants in tap water,
which unfortunately do exist and are very
prominent in essentially all regions of the world.
So please do get some information about what's coming out of your tap.
I also want to throw in one other piece of information that's really critical that I learned
about when researching this episode, which is the quality of water that comes out of your
tap is not just dictated by the source that it comes from, external to your home or apartment.
Your pipes are also important, and that filter,
or that little mesh that sits at the faucet head,
is also very important.
Most people don't pay attention to that,
but turns out that a lot of debris and contaminants
can be derived from that little filter
that most people just simply aren't cleaning often enough.
So here I'm not trying to tell you that the metal or the plastic that that filter is made
of is a problem.
More often than not, contaminants are showing up in water because people aren't cleaning
those filters often enough.
And in fact, prior to researching this episode, I didn't ever think to clean that filter.
I looked underneath my faucet and while that I didn't ever think to clean that filter. I looked underneath my
faucet and while that filter didn't look particularly filled with debris, I did find that when I took
it off and I looked at the other side, there was quite a lot of debris. So if you are going to
consume tap water, you definitely want to consider the source, the pipes in your building or
apartment, the ones that lead right up to your glass or jug that you would put that water into and also
that mesh that that water passes through as it goes into that glass or jug.
We also talked about how much water to drink.
I hope that we finally resolved that question for those of you that have been wondering
about that.
The Galpin equation is a wonderful approach to how much water to consume during exercise
and by providing these other formulas
of about eight ounces or 240 milliliters of water per hour
for the 10 hours from waking until post waking
on average, remember it's averages,
you don't have to consume them every hour on the hour,
and no need to be neurotic.
Hopefully you can achieve better levels of hydration,
which we know can lead to reductions in blood pressure,
improvements in appetite, mood, and focus. can lead to reductions in blood pressure, improvements
in appetite, mood, and focus. And I really think that it's the improvements in cognitive
focus and physical ability, both endurance, strength, and other forms of kind of readiness
in the body, readiness to perform work in the body, that really are best supported by the
hydration literature. And then, of course, we went through the different forms of water
that you hear about out there and addressed which ones are going to be beneficial
or not, and perhaps more importantly why any of them would be beneficial. Thinking about that from
the perspective of biologists and the chemistry of water, and I do hope that by arriving at this
point in the episode now that you have a much better understanding of the chemistry and physics of
water and the way that water can powerfully impact your biology.
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Thank you once again for joining me for today's discussion,
all about the science, including the chemistry, physics,
and biology of water, and how your body utilizes water.
And last but certainly not least, thank you
for your interest in science.
and last but certainly not least, thank you for your interest in science.