This episode I discuss the hormones testosterone and estrogen and how
they impact the brain, body, and behavior at ages after puberty. I
also discuss how various behaviors such as exercise (resistance and
endurance training) and sex, or observing sex impact these hormones
and their levels. I ask: "what specifically is it about such
activities that impact testosterone and estrogen?"; the resounding
theme is that when our nervous system is activated in particular ways
it drives our endocrine system and vascular system to activate or
repress certain hormone networks in predictable ways. I also discuss
peer-reviewed studies and protocols addressing (at a mechanistic
level) how light, cold and heat, and respiration (breathing) can
positively or negatively impact testosterone and estrogen. And we
discuss specific supplements and compounds that peer-reviewed studies
illustrate can adjust testosterone and estrogen levels: by changing
their binding to other proteins, by raising them directly, or by
changing other hormones released from the brain and pituitary. I
discuss optimization in the normal reference ranges for these
hormones, and I discuss pheromones, apnea, menstrual cycles, menopause
and andropause. As always a mix of basic science, biological
mechanisms and tools and protocols are discussed.
- Introduction
- Hormone Optimization
- Salutogenesis: A Powerful Way to Conceptualize Health
- Estrogen and Testosterone: Sources, Levels & Ratios
- The Power of Competition, Plus: Anxiety, Persistence & Dopamine
- Testosterone & Libido Pre-Ovulation
- Estrogen & Sexual Receptivity; Libido In Males
- How Sex Behavior Impacts Testosterone: Observing vs. Actual vs. Abstinence
- Testosterone & Prolactin: Sex Seeking vs Pair Bonding
- DHEA (dehydroepiandrosterone): Effects on Levels/Ratios
- Behaviors That Decrease Testosterone (& Cortisol): Parenting & Prolactin
- How Illness Impacts Testosterone & Estrogen: Cytokines, e.g., IL-6
- How Exactly Do Behaviors Change Hormones?
- Pheromones: Miscarriage, Menstrual Cycles, Puberty Onset, & Mate Recognition
- Apnea: A Powerful Bi-Directional Influence On Estrogen & Testosterone
- Mouth vs. Nose Breathing & Hormone Levels: Effects Via Sleep and Direct Effects
- How Sleep Adjusts Cortisol/Testosterone and Cortisol/Estrogen Ratios
- 02:CO2 Ratios, Nasal Breathing During Exercise
- Light Viewing Patterns & Hormones: Dopamine, GnRH
- Spring Fever: Tyrosinase, Hair Color, Mating Frequency
- Specificity of Hormone Effects
- Temperature: Cold & Hot Gonads
- How To Exercise: Types, Effort Level, Sequencing
- Cardio/Endurance vs. Resistance Training (First or Last?) Yes, It Matters
- Estrogen & Menopause: Compounds That May Ameliorate/Reverse Symptoms
- Nutrients That Optimize The Foundation For Hormones
- Opioids as Severe Hormone Disruptors
- Testes, Antlers & Ovaries
- Creatine & Increasing DHT (Dihydrotestosterone)
- Free and Bound Testosterone: SHBG (Sex Hormone Binding Globulin), Tongat Ali
- Nettles, Prostate, Boron, & Blood Brain Barrier
- Hormone Related Cancers: Sometimes Reducing Estrogen and Testosterone Is Optimal
- Ecdysteroids: Mimic Mammalian Hormones
- Optimizing Brain Hormones: Chorionic Gonadatropin, Fadogia Agrestis
- Additional Compounds, Liver Toxicity, Overall Milieu
- Summary: And Note About Additional Related Topic Coverage Coming
- HubermanLab #Testosterone #Estrogen
-- Welcome to the Huberman Lab Podcast, where we discuss science and
science-based tools for everyday life. [upbeat music] I'm Andrew
Huberman, and I'm a professor of neurobiology and ophthalmology at
Stanford School of Medicine. This podcast is separate from my teaching
and research roles at Stanford, it is, however, part of my desire and
effort to bring zero-cost-to-consumer information about science and
science-related tools to the general public. Before we begin today,
just want to acknowledge that if you're watching this on YouTube, yes,
I have a bandage on the left side of my face, I was trying to cook
something for Costello and I and I got burned, burned myself, it was a
cooking accident. I'm fine, no need to dwell on it, we can move on,
but I just wanted to let you know everybody's going to be okay, he got
a great meal, I got a burn and a great meal. Today's episode is
brought to us by Four Sigmatic. Four Sigmatic is a wellness company
that makes mushroom coffee. For those of you that haven't heard of
mushroom coffee before, I just want to make clear, these are not
psychedelic mushrooms, and no, the coffee does not taste like
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started using Four Sigmatic coffee a few years ago and then we
actually stocked it in my lab, we still stock it in my lab because it
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research studies done independently, as well, it has Chaga mushroom,
Chaga mushroom has been shown to increase growth factors that impact
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sign up at blinkist.com/huberman. Today's episode is also brought to
us by Theragun. Theragun is a handheld percussive therapy device that
releases deep muscle tension. I was introduced to Theragun on a dive
expedition for my laboratory a few years ago. On that expedition, we
were working very hard, we were diving all day, we were carrying
pelican cases with equipment, we were carrying tanks, very sore, very
tired by the end of the day, as was everybody else. Someone brought
along a Theragun, and pretty soon, that thing was getting passed
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with physical work, exercise, even just sitting too long throughout
the day, so when I got back, I got a Theragun, I still use the
Theragun daily, it's terrific because it's very quiet so you can use
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also a 30-day money-back guarantee, so if you don't like the product,
you send it back, you get your money back. This month on the "Huberman
Lab Podcast," we're talking all about hormones, these incredible
chemicals that can impact our mood, our behavior, our feelings of
optimism or pessimism.
The amazing thing about hormones is that hormones impact all those
things, but all those things, how we feel and what we do and what we
think also can impact our hormones, and so it's a really fascinating
area of biology that impacts every single one of us every day both in
wakefulness and in sleep and throughout the lifespan. Today, we're
going to be talking about hormone optimization, and we're mainly going
to be focusing on estrogen and testosterone and their derivatives.
Last episode of the "Huberman Lab Podcast," we talked about sexual
development, that is, how the chromosomes, the gonads, and hormones
impact what we call sexual development, leading all the way up to
puberty. Today, we're mainly going to talk about processes that happen
from puberty onward, although we might talk a little bit about
development as well, so today, we're going to talk a lot about basic
biology, but we're going to weave in a lot of practical tools along
the way for how to optimize these incredibly powerful things that we
call hormones. Before we dive into our discussion about hormone
optimization, I want to raise what I think is a very important point
that at least I hadn't heard of until recently, which is the concept
of salutogenesis.
Many of us are familiar with the concept of pathogenesis, the idea
that there are all these scary diseases like dementia and heart
disease and stroke, and all these things that await us if we don't
take good care of ourselves and that might await us even if we do,
that's the pathogenic model, salutogenesis is something I learned
about from one of my Stanford Medicine colleagues, which is a
different orientation toward health and well-being where you're taking
on particular behaviors, you're taking on a particular stance towards
nutrition and exercise, supplementation, et cetera, in order to
promote well-being above where you would be if you were not doing
those behaviors. Now, if you think about it, these two things,
salutogenesis and the pathogenic model, are really two sides of the
same coin, but I'll just give an example of how this might affect you
in a real way. If you like exercise because it feels good, great, but
many people exercise, or eat well, for that matter, in order to avoid
heart disease or to avoid dementia, to avoid negative changes in body
composition, and while that's powerful and certainly is the case that
exercise will help you move away from all those things, the
salutogenesis model differs in that it involves a mindset and an
orientation towards doing those things in order to feels good, in
order to enhance your level of energy, in order to improve endocrine
function and metabolic function, so it's really part of the pathogenic
model, and yet, salutogenesis is really more of a mindset toward why
you would do these particular behaviors, and really, the most powerful
mindset is going to be one where you are thinking about the pathogenic
model, doing things so that you don't end up sick, et cetera, and to
move away from sickness, as well as the salutogenic model where you're
doing things in order to move towards health and well-being. We think
of health and wellness nowadays, or the wellness community or wellness
practices, and in many ways, that is the essence of the salutogenic
model, but I found it very interesting to know that within the field
of allopathic medicine, these two models exist but we don't hear about
the salutogenic model quite as often, so it's just something to keep
in mind, especially because of some of the mindset effects that were
discussed in previous episodes, I'm not going to go into these in
detail again right now, but if you might recall from the episode on
food and mood, we talked about some of these incredible studies that
were done by Alia Crum's group at Stanford and others showing that if
you tell people that the behavior that they're about to do, in this
case, it was people cleaning up hotel rooms because that was their
job, if you tell them that it's good for them, then you see much
greater positive health effects than if they aren't aware of that
information that it's good for them, so we should really be thinking
about not just moving away from disease and negative things, but also
why certain things are good for us because it's well-established now
from really good scientific studies that keeping in mind the positive
effects of things can really have an outsized effect on well-being,
right down to the level of our physiology.
So let's talk about hormone optimization, today we're going to talk
about hormone optimization in reference to estrogen and testosterone
and their derivatives, now, estrogen and testosterone and their
derivatives are what we call sex steroids, now, the sex steroids
immediately call to mind sex, for obvious reasons, and steroids,
meaning anabolic steroids, but I just want to emphasize that estrogen
and testosterone are present in everybody, it's their ratios that
determine their effects, and so today we're going to talk about how
you can optimize their ratios depending on your particular life goals
because the ratio of estrogen and testosterone in every individual has
profound influence on feelings of well-being, feelings of optimism,
feelings of anxiety or lack of anxiety, on reproduction, on sexual
behavior independent of reproduction, they are profoundly powerful
molecules, and we all make these molecules, to some degree or another,
but there are also important behavioral tools, supplementation tools,
as well as prescription drugs that can impact the ratios of
testosterone and estrogen in really powerful ways, so we're going to
cover all of that. I want to emphasize that when you hear sex steroids
or steroid hormones, most people think about anabolic steroids, and of
course, anabolic steroids are derivatives of testosterone or
testosterone itself, and they are heavily used and abused in the
sports community as well as outside the sports community, but there,
of course, are many steroids that are not anabolic steroids that are
also abused in sports. Today, we're not talking about drugs in sports,
but I think that it carries such a heavy weight when people hear the
word steroids, they think about anabolic steroids, so while today's
discussion will certainly be relevant to physical performance, in
fact, we're going to talk about how specific types of exercise,
particular patterns of cold exposure, as well as particular patterns,
believe it or not, of breathing can impact sex steroid hormones, both
estrogen and testosterone, the discussion isn't really geared towards
performance enhancement in sport, although we will do an entire
episode, perhaps even an entire month related to performance
enhancement in physical enterprises. So one of the first things to
understand if you want to optimize your hormones is where they come
from. There are a lot of different glands in the body that produce
hormones, there's the pineal gland, some hormones are made in the
hypothalamus, hormones are made by the gonads, the ovaries or the
testes, you've got the thyroid gland, there are a bunch of different
glands that make these different hormones, but when we're talking
about the sex steroid hormones, estrogen and testosterone, the major
sources are ovaries for estrogen and the testes for testosterone,
although the adrenals can also make testosterone. Now, there are also
some enzymes, enzymes are things that can change chemical composition,
and the enzymes that we're going to talk about today are the
aromatases mainly, the aromatases convert testosterone into estrogen,
so in a male, for instance, that has very high testosterone, some of
that is going to be converted into estrogen by aromatase, and
aromatase is made by body fat, it's also made in the testes
themselves, a lot of people don't realize this, but the testes
actually have the capacity to manufacture estrogen and aromatase,
albeit at low levels, but this turns out to be important for
optimizing hormone levels in males at later points, and we'll discuss
that. It's important to note that there's a huge range in terms of the
levels of hormones, testosterone and estrogen, between individuals,
and it actually occurs within individuals across the lifespan, I'm not
going to throw out specific numbers of X picograms per deciliter, et
cetera today because that's going to vary a lot, it's going to depend
on whether or not you're measuring in picograms or nanograms and that
sort of thing, if you want to examine your hormones, you should do
that in conjunction with a medical doctor, ideally, an endocrinologist
can help you sort out that information, but the important thing to
know is that prepubescent females make very little estrogen, and when
we talk about estrogen, we mainly talk about estradiol, which is the
most active form of estrogen in both males and females. So
prepubescent females, very low levels of estrogen, during puberty,
levels of estrogen, AKA estradiol, basically skyrocket, and then
across the lifespan, estrogen is going to vary depending on the stage
of the menstrual cycle, but as one heads into menopause, which
typically takes place nowadays somewhere between age 45 and 60, levels
of estrogen are going to drop and then post-menopause levels of
estrogen are very low. As well, testosterone will fluctuate across the
lifespan, testosterone is going to be relatively low prepuberty in
males, during puberty, it's going to skyrocket, and then the current
numbers are that it drops off at about a rate of 1% per year, although
we're going to talk about some data that show that there's actually
tremendous variation in testosterone levels, there's actually a lot of
examples of men in their 90s, their 90s, who still have testosterone
levels that mimic pubertal levels, which is remarkable and speaks to
the huge variation in testosterone levels across individuals. So let's
talk about other sources of these hormones, and then it will make
clear what avenues you might want to take in order to optimize these
hormones. The other glands and tissues in the body that make these
hormones, testosterone and estrogen, as I mentioned briefly, are the
adrenals, so the adrenals right on top of the kidneys, and the release
of these steroid hormones from the adrenals, in particular
testosterone and some of its related derivatives, are mainly activated
by competition, so let's talk about competition because it turns out
that competition is a powerful influence on the sex steroid hormones,
and the sex steroid hormones powerfully influence competition.
So most people don't realize this, but most males of a given mammalian
species never get to reproduce, in fact, they never even get to have
sex at all, and we don't often think about that, but testosterone
plays a powerful role in determining which members of a given species
will get to reproduce, which ones of that species will actually get
access to females, and so here I'm not talking about humans
specifically, but it's well known in species like elephant seals, in
species like antlered animals and rams, for instance, that the higher
levels of testosterone correlate with access to females. Now, one
interpretation of this is that the females are detecting which males
have high testosterone and selecting them, they're more receptive to
them, we're going to talk about receptivity for mating in a moment,
but it's actually more so that the males that have higher testosterone
forage further and will fight harder for the females, and this is
really interesting because there's very good evidence now that
testosterone can reduce anxiety, promote novelty-seeking, and promote
competitive interactions, and so before you leap too far with this in
your mind and think about all these human behaviors, just stay with me
because there's a little bit of biology here that makes it all make
sense and it turns out to be pretty simple. We have a brain region
called the amygdala, in Latin, that just means almond, but the
amygdala is most famous for its role in fear, we hear a lot about fear
and the amygdala, but that the amygdala is really involved in threat
detection, it sets our thresholds for anxiety and what we consider
scary or too much, testosterone secreted from the gonads and elsewhere
in the body binds to the amygdala and changes the threshold for
stress, so I've said before on previous versions of this podcast and
on other podcasts that testosterone has this incredible effect of
making effort feel good, but what I was really referring to is the
fact that testosterone lowers stress and anxiety, in particular, in
males in a given species. Now, this is important because we often
think of testosterone as creating, whatever, masculinization or it's,
you know, virilization, or all these terms are thrown around, but
what's it really doing when it comes to mate choice and competition?
What it's doing is it's reducing the threshold for anxiety, and in
doing so, it selects individuals of a given species to push further,
being willing to suffer more, although it also reduces pain, so maybe
they also suffer less, in pursuit of reproduction and females. Now,
it's well known in humans that both males and females who have
elevated levels of testosterone will engage in more novelty-seeking,
and I do want to point out that even individuals without testes have
testosterone, and peaks in testosterone have similar effects
regardless of whether or not someone has ovaries or testes,
testosterone increases generally lead to more foraging, more novelty-
seeking, increases in libido, and increases in desire to mate, so it
is the case that increases in testosterone promote competitive and
foraging-type behaviors in humans and in nonhuman mammals, but it's
also true that competition itself can increase androgens, such as
testosterone, I want to repeat that, competitive environments
themselves can increase testosterone. Now, some people have come to
the conclusion that if you win, your testosterone goes up, and if you
lose, your testosterone goes down, and to some extent, that's true,
but that's not a direct effect on the gonads, that's actually mediated
by the neuromodulator dopamine, we talked about dopamine in the
episode on motivation and drive, and dopamine and testosterone have a
remarkable interplay in the body, dopamine is actually released in the
brain in ways that has the pituitary, this gland that sits over the
roof of your mouth, release certain hormones that then go on to
promote the release of more testosterone, and indeed, winning promotes
more dopamine, and later, more testosterone, however, in the short
term, just competing increases testosterone independent of whether or
not you win or lose, so the short version of this is that competition
increases testosterone, and this may be an ancient mechanism whereby
the androgens, such as testosterone, are feeding back to encourage
more competitive-type behaviors because every species, whether or not
you're talking about reproduction or other resource allocation, is
involved in competition, not every individual of a species gets access
to the same number of mates or the same quality of mates, and this is
true in both directions, for males and females and everything in
between. So I just want to emphasize once more in case I went through
it too quickly that increases in testosterone in females are also
going to lead to increase in reproductive behavior or seeking out
reproductive behavior, they increase libido, in fact, there's a
particular phase of the menstrual cycle where testosterone peaks just
before ovulation that, on average, leads female humans to seek out sex
more than they would otherwise during their cycle, and this is all by
self-report, but this is also while measuring things like
testosterone-estrogen ratios, and so forth, so it's really interesting
that a single molecule, regardless of chromosomal or gonadal
background, is increasing seeking of mates across individuals,
increasing desire to compete or willingness to compete, and lowering
the threshold for stress and anxiety.
It's important to point out that while increases in testosterone
promote seeking of mates and reproduction in both males and females,
in females, it's actually increases in estrogen that promote
receptivity to mating, so testosterone is driving the seeking of sex
and estrogen is promoting the actual act of sex from females, so-
called receptivity, consensual receptivity. In males, it's interesting
to point out that testosterone is promoting seeking of sex, but it's
also estrogen in males that's important for libido, if estrogen levels
are brought too low, then men will completely lose their libido, this
is often not discussed or overlooked in the discussion about
testosterone therapy and performance-enhancing drugs, people think
that hyperandrogenized individuals, meaning people that have very high
levels of androgen will have very high levels of libido, and they
will, provided estrogen is available in sufficient ratios to match
that testosterone, so it's not simply the case that high levels of
testosterone produce a lot of sex and mating behavior and low levels
of estrogen are good across the board, you actually need both in both
males and females, it's just that in females, the testosterone levels
are always going to be lower than the estrogen levels, and in males,
the estrogen levels are always going to be lower than testosterone
levels, so testosterone promotes sex-seeking behavior, and the real
question then is, does sex itself promote testosterone?
And the answer is somewhat complicated, but the short version is yes,
and as you recall, sex has multiple stages, so there's the physical
act of sex, there's the seeking of sex, and then there's orgasm and
ejaculation. Now, it's important to distinguish between these because
whether or not sex itself increases testosterone depends on whether or
not the male ejaculates, and this is very important to understand
because on a previous episode, I mentioned how dopamine increases with
sexual activity, remember, dopamine and testosterone tend to increase
linearly with one another, but then after ejaculation, there's a
release of prolactin, and prolactin actually sets the refractory
period in males during which he can't have sex again, and the duration
of the refractory period will vary tremendously depending on how much
and how long that prolactin release occurs. I also described in a
previous episode how some people take vitamin B6, I'm not suggesting
anyone do this, but take vitamin B6 in order to reduce prolactin
levels and thereby reduce the duration of the refractory period, but
getting at this question about testosterone and sexual behavior, it's
important to distinguish between these different phases of
reproduction or reproductive behaviors, so there are studies showing
that sexual behavior itself can increase testosterone, there was a
study published in 2011 from Escasa et al., E-S-C-A-S-A, this is the
stuff of textbooks, this is on PubMed, these are quality studies,
showing that men who observe sex, so I guess this would be observing
pornography, will have slight increases in testosterone during the
observation, these people actually were willing to have blood draws
taken while watching pornography, they had increases in testosterone
that were very modest, of about 10%, whereas when people participated
in sex, so they actually did this study where people had blood draws
and they had real sex with their partners, and they had 70% increases
in testosterone, so there are increases in testosterone that are quite
significant during the physical act of sex and far less so during
observing sex. Now, the question that I often get, in fact, it's one
of the questions I get most often in the comments on YouTube, I don't
know why that is, is whether or not ejaculation adjusts testosterone
levels, and it turns out, there are two studies that I could find that
were quality studies on PubMed that address this, that sex and
ejaculation itself does not reduce testosterone levels although it
will increase prolactin levels for the reasons I described a moment
ago, however, abstinence or sex without ejaculation for a week or more
will increase testosterone levels up to 400%, so the answer is
actually complicated, it's not straightforward, what it means is that
sex itself increases testosterone, however, abstinence also increases
testosterone even further, so it's a nuanced answer, and I hope this
is satisfactory, no pun intended, to those of you that have been
asking me, what is the relationship between sex and ejaculation and
testosterone and dopamine? It is nuanced, and you have to understand
that nuance if you want to understand how certain behaviors impact
hormones and how hormones impact those behaviors. As I mentioned
before, in females, testosterone also primes the motivation to seek
out sex, and sex itself also increases testosterone, but it also
increases prolactin, so in both men and women, sex increases prolactin
post-sex, it's just the way that the system works, it's that
testosterone and dopamine increase in the seeking-out and the behavior
of sex, and then after sex, prolactin levels go up, there's kind of a
quiescence, the whole nervous system is promoted towards calm, and
this may actually have something to do with pair-bonding and the
encouragement of individuals to spend more time together to exchange
different smells and hormones, and maybe even pheromones, and we're
going to talk about pheromones in a moment.
A few years ago, there was a lot of excitement about the hormone DHEA,
which is mainly made by the adrenals, DHEA has been promoted as kind
of a catch-all for increasing testosterone and estrogen in males and
females, and indeed, DHEA will increase both testosterone and
estrogen, this is something to be mindful of if you're thinking about
taking DHEA or you're taking DHEA already.
DHEA will increase both testosterone and estrogen, and the extent to
which it increases one or the other will depend on whether or not
you're starting off with more estrogen than testosterone or whether or
not you're starting off with more testosterone than estrogen and
whether or not you have a lot of aromatase, so for individuals that
have a lot of aromatase being made by the testes or by body fat, if
you take DHEA, there's a good chance that a fair portion of that is
going to be shuttled towards estrogen production and not towards
testosterone production, whereas in individuals that have low levels
of testosterone to begin with, high levels of estrogen, there's a good
chance that the DHEA is going to promote mainly estrogen production,
at least that's what I could find from the research studies that I
examined. So the way to think about DHEA, it's a kind of global
promoter of the sex steroid hormones, and its specific effects are
going to depend a little bit on where you started and whether or not
you have ovaries or testes.
So just as there are behaviors that can increase testosterone, there
are behaviors that can decrease testosterone, and one of the most
well-characterized ones in humans is becoming a parent. So expecting
fathers have an almost 50% decrease in testosterone levels, both free
and bound testosterone, as well, their cortisol levels, a stress
hormone, drop by almost three-fold, which is incredible, and their
estradiol levels double, so their estrogen levels double, so expecting
fathers many people have known put on additional body weight, everyone
always thought that it's because they're eating in parallel with their
pregnant wife, but it turns out that these effects of reduced
testosterone, increased estradiol, and reduced cortisol can all be
explained by an increase in prolactin, so not just in humans, but in
other species as well, when the male and female of that species are
expecting young, they lay down more body fat, the assumption is that
this is to prepare for long nights of no sleep, which occurs in many
species, not just in humans, so it's really interesting that this
hormone, prolactin, can start suppressing whole categories of
hormones, sex steroid hormones, and can start increasing whole
categories of other ones, so we hear about the dad bod, there are a
lot of explanations for the dad bod that extend well beyond this
podcast episode, but it is a well-known phenomenon that testosterone
is going to drop, prolactin's going to increase, estradiol's going to
increase in males and females that are expecting children. Now, how
long that lasts is very interesting, it actually has to do with how
much contact and how much contact with smells of the baby, of the
offspring, the father happens to have, so how available or unavailable
he is will actually impact his level of hormones, now, I'm definitely
not promoting the idea that fathers or mothers take time away from
their offspring in order to keep their testosterone levels high or to
restore them, that's not what I'm saying at all, it's just interesting
to point out that these evolutionary mechanisms push us toward or bias
us toward particular categories of behaviors by influencing our
hormones, which then feed back and promote more of that particular
behavior because as I mentioned before, peaks in testosterone in males
and females cause individuals to seek sex, not promote parenting,
whereas reductions in testosterone, increases in prolactin, and
decreases in cortisol move individuals of both sexes toward parenting
behavior and less toward reproductive behavior. The other behavior
that markedly reduces testosterone in both males and females and
markedly reduces the desire for seeking sex and sex itself is illness,
and many of you might say, "Well, duh, when people feel sick, "they
don't feel like seeking out mates, "they don't feel like having sex,"
but have you ever wondered why that actually is?
Well, it turns out that it can be explained by the release of what are
called inflammatory cytokines, so cytokines are related to the immune
system, they travel in the lymph and in the blood, and they attack
invader cells like bacteria and viruses, and under conditions of
illness, we make a lot of different cytokines, some of them are anti-
inflammatory, but some of them are pro-inflammatory, and the best-
known example of a pro-inflammatory cytokine is IL-6, and it's known
that IL-6, when injected into individuals, will decrease the desire
for sex and eventually will reduce levels of testosterone and estrogen
independent of feeling lousy, so the reason why people don't want sex
when they're sick is because levels of IL-6 are increased. Now, this
is important because as we start to think about the different ways to
modulate the sex steroid hormones, so-called optimize the hormones,
keeping levels of IL-6 low is going to be important for them to exert
their effects, now, IL-6 doesn't just travel to the gonads and shut
down the gonads, it actually has ways to interact with some of the
receptors that the steroid hormones, estrogen and testosterone, bind
to, and impact those receptors so that the sex steroid hormones can't
have their effect. In short and put simply, inflammatory cytokines
like IL-6 are bad for sex steroid hormones, and so we're going to talk
about how to modulate IL-6 in the direction that you would want and
how to increase another cytokine called IL-10, which is anti-
inflammatory in ways that can help promote, or at least support, the
sex steroid hormones. So as we move forward, we're going to now start
to consider what sorts of behavioral practices, as well as other
things, can modulate the sex steroid hormones in the directions that
you want them to go, but before we do that, and in order to set the
stage for that, you should be asking yourself, how is it, or why is
it, at a mechanistic level, that behaviors can modulate hormones at
all?
If you think about it, it's kind of strange that just the mere act of
being a parent or parenting can change testosterone levels so
dramatically or estradiol levels so dramatically, what is it? Is it
the sweat of the baby? Is it their saliva? Is it the sight of the
baby? Is it holding the baby, or is it all those things? It turns out
that many of those effects are because of smell, or in some cases,
even possibly pheromones. Now, I talked about hormones, hormones,
again, are a chemical, travels in the body, impacts tissues and cells
elsewhere in the body, a pheromone is a chemical that's released by
one member of a species that goes and impacts members elsewhere, but
of the same species, or even of other species.
Now, pheromone effects are absolutely well-established in lots of
animal species, but they are very controversial in humans. Today, I'm
going to talk about some of the well-established ones in animals, I've
mentioned one or two of these before on previous podcasts, but I
haven't mentioned several of them, and I'm going to talk about the
evidence for pheromones in humans that are well-established. So the
main ones in animals that are discussed are called the Lee-Boot
effect, the Whitten effect, the Bruce effect, and the Vandenbergh
effect, named after the people that discovered them. The Lee-Boot
effect is when you house females of a given species together with no
males, they start displaying longer, what are called estrus cycles, in
many species, they don't have menstrual cycles, which are 28 days,
they have estrus cycles which tend to be four days or some variant
thereof. It's an interesting phenomenon because what it means is that
the presence of the male itself is changing the ovulation cycle. Now,
many people out there, I imagine mostly the people that are ovulating
out there will say, "Of course, I notice I ovulate differently, "or my
cycle changes when I'm in the presence of my partner "or I'm not," but
the pheromone effect that mirrors this Lee-Boot effect in humans has
still not really been identified, nobody knows what the exact chemical
is, but nonetheless, this is a strong effect in some animals. The
other one is the Bruce effect, and this is a very dramatic effect
whereby a pregnant animal will abort or reabsorb her fetus if the dad
of those animals, the father that sired the litter, because these are
animals, they're litters, is removed and a novel male is placed in her
vicinity for about 48 hours, and what's interesting is the way that
this happens is a pheromone that comes from male urine activates the
gonadotropin-releasing hormone system and causes a reintroduction of
the estrus cycle and a spontaneous abortion of the fetus. Now, a lot
of people have taken the Bruce effect kind of to its extreme and asked
whether or not in humans, miscarriages are caused by detecting the
pheromones or odors of novel males, meaning the non-dad male, and
that's still an open question, nobody knows if that's true or not, so
I want to emphasize that. The other one is the Vandenbergh effect, and
this is one I alluded to in a previous episode of the podcast, which
is that puberty in females can be accelerated by placing a novel
sexually competent male in with a young female who has not undergone
puberty. There's also a version of this, which I haven't described,
which is delay of puberty where you take juvenile female animals that
have not undergone puberty and you put them with more mature females
of the same species, and that introduction of more females will cause
a delay, a significant delay in the onset of puberty. So these are all
pheromone effects, and we know they're pheromone effects because
they're not conscious, they also don't require actual contact with the
other members of a given species, these are all effects that can be
mediated by the urine from a given species or by the sweat of a given
species, and speaking of sweat, the one pheromone effect that I'm very
aware of from the published literature is a paper that was published
in 1998 by Stern and McClintock which was getting at this question of
synchronization of menstrual cycles. Now, the whole idea of
synchronization of menstrual cycles is pretty controversial, for a
long time, people said, "Oh, this is absolutely a well-characterized
phenomenon," people in dormitories, their menstrual cycles would
synchronize, people living in environments together, their menstrual
cycles would synchronize, and then some studies came out that kind of
undercut those data and said no, this actually doesn't happen, and it
was kind of controversial, but there is a very clear effect that was
described by Stern and McClintock, what they did actually was they
took females, they charted their cycles, and then they had other
females wear pads in their armpits and they collected sweat from those
females, and then they took the sweat from those pads in those
female's armpits, and they introduced them to women who had never had
contact with the people who had sweated, they only had contact with
their sweat, in fact, they swabbed it underneath their nose, and if
that sounds gross, they dilute it in alcohol, so much so that they
can't actually detect the odor of the sweat, that's actually very
important because it's not the smell, it's the pheromone chemical
itself, and it turns out the pheromone chemical itself can modulate
the menstrual cycle, although it doesn't necessarily synchronize it
with the sweater, what it does is it changes the duration and the
pattern of ovulation relative to the so-called follicular phase, long
and short of this is that the sweat and pheromones of females can
modulate the menstrual cycle patterns of other adult females, it's
just a question of whether or not they synchronize, and if you're kind
of rolling your eyes now and saying, "Well, of course they do, "and
this is really detailed," this is how the science is done, and the
reason why people are so skeptical about the presence of pheromone
effects in humans is that there's no well-identified pheromone organ,
you know, we have an area of our nose that's responsible for smelling,
that's well-established, it's been observed in MRIs many, many times,
in cadavers many, many times, in pretty much all individuals, but the
vomeronasal organ, which is the pheromone-detecting organ, hasn't
really been found in humans, there's something called Jacobson's
organ, which is thought to be the organ in the nose, it's actually on
the top of the roof of the mouth and in the kind of back of the nose,
this is for you wine tasters, I never can pronounce this, what are
they called, sommelier, whatevers, the people that are excellent at
drinking and detecting the essences of wine that you have to go
through all these tests in order to get certified as one of them,
somebody tell me, they are using probably a similar mechanism of
mixing taste and smell, and Jacobson's organ, if it exists, the
vomeronasal equivalent in humans, is thought to be a combination of
smell and taste. Now, it gets even weirder and cooler when you think
about a given study that was done in humans where if you take hundreds
of t-shirts from boyfriends, keep them separate, you take those
t-shirts, you wash them many times separately, and then you offer them
to the girlfriends, the long-time partners of those guys, and what
you'll find is that the girlfriend can pick out her boyfriend's
t-shirt among hundreds of other t-shirts, not because it smells
different, but because something about it seems different, it might
smell different to her in some way that's kind of imperceptible even
to her, and the level of accuracy in detecting that t-shirt, her
partner's t-shirt, is way above statistical significant thresholds, so
much so that you almost have to say there's something about these
effects that are real pheromone effects, although people still argue
that there are no pheromone effects in humans, that it's all through
olfaction, I think these are interesting and important to understand
because it means that a lot of things coming through our nose, whether
or not it's pheromones or smells, are impacting hormones and our
ability to attach memories and kind of recognition of mates and other
people, including our children, not just our mates, and of course,
perfume manufacturers have really picked up on the idea of pheromones
and have entire laboratories set up to build chemical compounds into
perfumes that are designed to attract other mates, this is a well-
established and well-documented phenomenon. And the last point I'll
make about pheromones is that this combination of taste and smell is
such a real thing in the animal world that there's something called
the flehmen response, during the mating seasons for different animals,
you can actually even see this in horses, but for animals that are
seasonal maters, they'll do something called the flehmen response
where they actually open their lips and their mouth and they expose
their gums so that they can capture pheromones that are floating in
the wind in the environment, they actually are looking for mates using
their mouth and kind of sniffing around. If you own a dog and you
watch the way that the dog will sniff around selecting where they want
to urinate, males and females, they're bringing molecules into their
nose, I know it sounds kind of gross, sniffing urine, but there are a
lot of pheromones in urine of animals, a lot of pheromones that are
traveling in the wind, again, whether or not this is happening in
humans, I don't know, but then you think about the perfume thing, and
here people are putting these scents on themselves that contain
putative pheromones, human pheromones, and walking around hoping that
their scents are going to evoke mate-seeking behavior from other
individuals of the same human species, so we are among the animals in
this behavior, independent of whether or not you believe pheromone
effects exist. So let's get back to behaviors that can help optimize
hormone levels.
One of the main behaviors that's been shown to be associated with poor
levels of estrogen relative to age-match controls for people with
ovaries or lower levels of testosterone compared to age-match controls
for people with testes, is apnea, apnea has everything to do with
under-breathing and the buildup of too much carbon dioxide in the
body, there are other effects of apnea as well, but if there's a
consistent literature in this whole story about aging and reductions
in hormones and general health and reductions in hormones, it's apnea.
I went deep into the literature on advanced menopause, or when
menopausal symptoms are exacerbated, and I went into the literature on
andropause, or early-onset andropause, or levels of testosterone that
are far lower than they should be for a given age, and in every case,
you could find multiple papers that show that apnea, or poor
efficiency of breathing and buildup of too much carbon dioxide in the
body was a problem, mostly sleep apnea, although apnea in general was
shown to be an issue negatively impacting hormones. Now, the
directionality of this effect isn't entirely clear, it could be that
reductions in estrogen cause apnea, and actually, there's some reason
to believe that might be the case, I found at least one paper showing
that there are estrogen receptors on some of the neurons that actually
innervate the lungs and allow for the perception of how full or empty
the lungs are, in other words, reductions in estrogen may adjust
breathing by changing our sensitivity to our own lungs, now, that was
true for males and females, remember, estrogen is both males and
females, but as well, I found papers in which testosterone reductions
were associated with apnea, and testosterone receptors are also found
on a lot of cells in the so-called viscera, including the lungs, so
again, the directionality of the effect isn't clear, but what's really
interesting is that there are very clear ways in which patterns of
breathing, especially patterns of breathing in sleep, can modulate
hormones in ways that are immediately actionable and can serve to
optimize both estrogen and testosterone regardless of whether or not
you have ovaries or testes. So what is apnea? Apnea is under-
breathing, or mainly, cessation of breathing during sleep, so people
are holding their breath, and then they'll suddenly wake up, and
actually I've talked about the physiological sigh on previous episodes
of this podcast, of this pattern of double inhales followed by exhales
that one can do consciously to reduce stress and anxiety and offload
carbon dioxide, that pattern of breathing is actually what kicks in
spontaneously anytime we have an apnea episode in sleep, although in
many people who have apnea, they don't engage the physiological sigh.
People who are dramatically overweight also suffer a lot from apnea
during sleep, there's actually a lot of buildup of carbon dioxide in
the body, and that can lead to excessive sleepiness during the day,
inability to access the deeper phases of sleep, and it's well-
established that going into deep sleep and getting the proper patterns
of slow-wave sleep and REM sleep are important for hormone
optimization. I talked about how to modulate sleep and optimize sleep
in the first month of the "Huberman Lab Podcast," so please check out
those episodes if you have sleep issues or you want to work on your
sleep, also check out Matt Walker's terrific book, "Why We Sleep," and
that will help you find various protocols to help you optimize your
sleep, but the issue of breathing itself can be adjusted in the
daytime waking hours in ways that can powerfully impact both sleep,
reduce incidents of sleep apnea, and apparently from some emerging
literature, can also help to optimize various hormones even just by
breathing in particular ways while awake. So here's how this works,
there's now a lot of literature showing that breathing through the
nose, not through the mouth, is powerful for improving lots of things,
first of all, it improves cosmetic features of the jaw and face, this
was first well-established by my colleagues at Stanford in a book
called "Jaws: The Story of a Hidden Epidemic," this is by Sandra Kahn
and Paul Ehrlich, who are both faculty at Stanford, has a forward by
Robert Sapolsky, the great Robert Sapolsky, and it also has a heavy
endorsement upfront by Jared Diamond, the author of "Guns, Germs, and
Steel," the Pulitzer winner, so a lot of heavy hitters on this book,
"Jaws."
It's not a book that a lot of people know about, unfortunately, but it
really describes the benefits of nasal breathing and the terrible
things that happen when people, in particular children, but adults
also, are heavy mouth-breathers, so mouth-breathers have changes in
the cosmetics of their face and jaw that are really bad in terms of
attractiveness, and this was done in twin studies, you can look in the
book and see some of this, it's really dramatic how being a mouth-
breather tends to make the chin drop back behind the upper mandible,
there's a lengthening in the face, a drooping of the eyes, it can be
quite dramatic or modest depending on how much mouth-breathing. Now,
sometimes we have to breathe with our mouths, but there's also a lot
of data and studies described in this book, "Jaws," that describe how
nose-breathing in wakefulness and in sleep promotes all sorts of
positive things related to not just cosmetics, but also the
improvement of gas exchange of carbon dioxide and oxygen in the body,
and as well, it can modify levels of different neurotransmitters and
neuromodulators in ways that positively can impact hormones, so
believe it or not, being a nasal-breather and avoiding being a mouth-
breather can actually positively impact hormones, and in particular,
the hormones testosterone and estrogen, although the way that it does
that is by making you a better sleeper, which allows you to produce
more testosterone and the appropriate amounts of testosterone and
estrogen, but it does that in part through indirect mechanisms because
deep sleep supports the gonads, the ovaries and the testicles and
their turnover of cells and the production of cells, remember, in the
ovary, particular cells and the egg follicles themselves make
estrogen, and in the testicle, that the sertoli cells and the Leydig
cells are important for the formation of sperm and for testosterone,
respectively. So what does this all mean? This means we have to be
breathing properly, it almost sounds kind of like, kind of new-agey,
like, oh, you have to breathe properly to get your hormones right, but
no, you have to breathe properly to get your breathing and sleep right
so that your sleep can actually be deep enough and you're not entering
apnea states, and then that will support gonad function, and I
wouldn't be putting this out as one of the main behavioral tools
upfront if it weren't for the fact that the effects of apnea on these
hormones are dramatic and terrible, and the positive effects of
getting breathing right on these hormones, testosterone and estrogen,
are dramatic and wonderful, so let's talk about a few of those studies
briefly so I can underscore the value of proper breathing in order to
optimize hormones. So I was able to find at least four quality studies
showing that when apnea is reduced in sleep, or eliminated, there are
significant increases in testosterone in males and in proper estrogen
to testosterone ratios in females, and the way that it works is very
interesting, apparently, it works by reductions in cortisol, now,
cortisol is a stress hormone that is released early in the day as we
wake up and serves healthy roles in protecting us against infection,
reducing inflammation, et cetera, but you don't want cortisol to be
too high, and you certainly don't want it elevated too long throughout
the day and night, and so we all know, because now we've been told a
lot in the last decade or so, that getting proper sleep is important
for all these aspects of health, getting proper sleep can really
offset all the reductions in testosterone and estrogen and reductions
in fertility that occur if we don't get enough sleep, but seldom is it
discussed how sleep actually adjusts things like testosterone and
estrogen, and it does it by modifying cortisol, so the molecule
cholesterol can be converted into testosterone or estrogen, but
there's a competition whereby the cholesterol will turn into cortisol
and not testosterone, or it'll turn into cortisol and not estrogen if
stress levels are too high, so the simple version of this is getting
your breathing right during the waking hours, meaning primarily,
unless you're working out really hard or there's some other reason
why, you're maybe eating or speaking, that you need to be breathing
through your mouth, you should be a nose-breather, there's really good
evidence for that now, and in sleep, you also want to be a nose-
breather because that's going to increase the amount of oxygen that
you're bringing into your system and the amount of carbon dioxide that
you're offloading, there are other positive effects of it as well, but
you're basically reducing apnea, breath-holding in sleep leads to
buildup of carbon dioxide and leads to increases in cortisol, which
then decrease testosterone and decrease estrogen in negative ways
across all sexes, okay?
So the simple version of this is get your breathing right, so how do
you do that, how do you get your breathing right? Well, for some
people that have severe sleep apnea, they are going to need the CPAP
machine, this is a machine that you actually put on your face and it
helps you breathe properly in sleep. Many people, however, are
starting to do this thing of taping their mouths shut, now, this
sounds a little bit extreme, and you certainly don't want to do this
in any way that's dangerous. James Nestor talked about this in his
book, "Breath: The New Science of a Lost Art," that simply taping shut
the mouth, with some tape that will allow you to open your mouth if
you really need to, during sleep can allow people to shift over from
being mouth-breathers and snorers to nose-breathers. In the daytime,
the best way to get good at nasal-breathing is to dilate the nasal
passages, 'cause a lot of people have a hard time breathing through
their nose, and one way to do this is to just breathe through your
nose more, and one way to do that is when you exercise, in particular,
cardiovascular exercise, most of the time, provided you're not in
maximum effort, you should be nasal-breathing.
Now, for a lot of people, nasal-breathing during exercise is hard at
first, but as you do it, because the sinuses have a capacity to dilate
over time, you'll get better at it, the sinuses, if you haven't ever
held a skull for, because of my job as a neuroscientist, I've held a
lot of skulls, taken a lot of brains out of a lot of skulls, I teach
neuroanatomy, and I've done that for, goodness, god knows how many
species I've done that for, including human, but what the sinuses are
is they're actually, what you've got are you got these little portals
in the bone that run, you know, up here and down here, behind the nose
and into the jaw, if you ever had a cold and your sinuses are stuffed
up, you feel like you have congestion here and here and around your
ears and in your cheeks and in your face, and that's because the
sinuses are actually portals where the bones are fused together and
interdigitated like this, but they're lined, of course, with mucus
membranes, and as you start to nasal-breathe more, the nasal passages
will start to dilate more, don't worry, you're not going to get giant
nostrils, but what's going to end up happening is you're going to have
an easier time breathing through your nose just from waking, so my
advice would be breathe through your nose while exercising unless
you're in maximum effort, pretty soon, what you'll find is you
actually can create more output than you would if you were breathing
through your mouth, and of course, there are exceptions to this, if
you're swimming, follow that breath protocol, for fighters and martial
artists, there's reason to do the kind of exhale breathing through the
mouth, that shh kind of thing, you know, there are reasons to do that
sort of thing for particular sports, but for most people who are kind
of recreational athletes or exercisers, learn to be a nasal-breather,
it has positive cosmetic effects, it reduces apnea, it offloads more
carbon dioxide, it increases lung capacity, it dilates the sinuses,
and it prevents apnea in sleep, so unless you have severe apnea and
you need the CPAP, becoming a nasal-breather can have all sorts of
positive effects by reducing cortisol, reducing apnea, and indirectly,
raising testosterone and estrogen in the proper ratios, so this might
seem kind of foundational and indirect, but when you go into the
scientific literature, it comes through as one of the most powerful
things that you can do that is zero cost, takes a little effort but
it's zero cost, and it has all of these positive effects across the
board, you know, both cosmetic and in sleep and hormonal, et cetera,
so that's the first piece of behavioral advice. The second piece of
behavioral advice relates to the viewing of light, and many of you
have heard me talk about this before, and I'm not going to belabor the
point that viewing bright light within the first hour of waking,
whether or not it's from artificial light or ideally, from sunlight,
has these powerful effects on sleep and wakefulness, but we have to
return to this if you want to understand how light can impact hormones
because hormones, light, and dopamine have a very close-knit
relationship, so much so that your light-viewing behavior can actually
have a direct effect on hormone levels and fertility, it can have a
direct effect on hormone levels and libido, it can have a direct
effect on hormone levels and your ability to heal quickly, and I'm not
talking about shining light on particular injuries, that may or may
not have positive effects, we can argue about that on a subsequent
episode, it may, but what I'm talking about is viewing light with your
eyes, so let's talk about that now because the scientific literature
on this are robust and they extend back several decades, and yet, I
think most people don't really understand how powerful this
relationship is between light, dopamine, hormones, and all the great
things that the sex steroid hormones do when they're available in your
body in the proper ratios.
In order to understand the powerful effects that light can have on the
sex steroid hormones, we need to understand seasonal breeding animals,
now, humans are not seasonal breeders, but if you understand the
biology of how light impacts various neurotransmitters and hormones,
you'll set yourself up for a deep understanding of what you should do
with your light-viewing behavior.
So several species of animals, many species of animals, in fact, like
rabbits and fox, and various mustelids, like ferrets and ermines,
change their pellage color across the seasons, this might be kind of a
duh, but fox in winter are often white or light gray, and those same
animals will be brown or darker-colored in the summertime and spring
months. Now, those same animals breed in the spring, and they shut
down breeding, they actually shut down ovulation, they often shut down
testosterone production in the winter months, so right now I'm just
correlating color of fur with tendency to breed, tendency to breed, as
we know, is going to be related to the levels of sex steroid hormones,
estrogen and testosterone. Now, why would these two things be linked?
Well, it turns out that dopamine is the link between them, so dopamine
has a precursor, that precursor is tyrosine, which is amino acid,
comes from food, and when dopamine levels are high, as I mentioned
before, there's a tendency for more gonadotropin-releasing hormone,
luteinizing hormone, follicle-stimulating hormone, all the hormones
that come from the hypothalamic-pituitary axis and stimulate estrogen
and testosterone release from the ovary and testes, dopamine basically
increases all of that. The precursor to dopamine is tyrosine, but the
precursor to a lot of the melanin-producing elements of cells that
give pigmentation, including for the hair, is tyrosine and tyrosinase,
an enzyme, so yes, the same amino acid-based pathway, and many of the
same enzymes that are devoted to dopamine and dopamine increasing the
sex steroid hormones are devoted to giving pigmentation to the hair
and skin, and this is why in the summer months, when days are longer,
animals are breeding more, and this is also why in the winter months
when days are shorter, animals are breeding less, this is also why in
humans, many people, not all, feel an elevation in mood in the spring
and summer months because of the amount of sunlight they're getting is
increased relative to the winter months. Now, some of you may be
saying, "I love the fall, I love the winter," sensitivity to light in
these dopamine systems has a strong genetic component, so you go to
some areas of the world, I have relatives who are Scandinavian, and in
some areas of Scandinavia, people know that there's a kind of seasonal
affective disorder, there's kind of a seasonal depression and people
get sadder and more quiescent in the winter, there's actually less
going out, and therefore, there's less sexual behavior, there's less
partying and things of that sort, but other people will say, "No,
during the winter months, I feel great "and I love the holidays around
winter," et cetera, so there's a lot of variation, but in general, the
pathway is the following, increased viewing of sunlight, and it has to
be to the eyes, it's not to the skin, increased viewing of sunlight
increases dopamine levels in the brain, increased dopamine levels in
animals and humans increases the amount of these melanocytes and the
activity of these melanin-producing cells, which give pigmentation to
the skin and hair, and indirectly, increase the amount of testosterone
and estrogen, and thereby, reproductive behavior, feelings of well-
being, social interactions, reductions in anxiety, et cetera, all of
which should make sense based on what we've talked about already in
terms of the biology and the impact of these steroid hormones on
various aspects of the mind and body. So how does this translate to a
protocol? This translates to the protocol of, if you want to optimize
testosterone and estrogen, you need to get your light-viewing behavior
correct, it's not just about optimizing your sleep, which is also
important, it's about getting sufficient amount of light in your eyes
so you have sufficient levels of dopamine, so the simple protocols for
that I've reviewed before, but it means getting anywhere from 2 to 10
minutes of bright light exposure in your eyes early in the day, it is
not sufficient to do this with sunglasses unless you have to do that
for safety reasons, it's fine to wear prescription lenses and
contacts, if you can't get sunlight for whatever reason, you want to
use bright artificial light, but that is absolutely critical for
timing the cortisol release properly, limiting cortisol release to the
early part of the day, getting increases in dopamine that are going to
promote the production of testosterone and estrogen to healthy levels,
the other aspect of light-viewing behavior that's extremely important
is to avoid bright light exposure to your eyes in the middle of the
night, if you're viewing bright light in the middle of the night, you
are suppressing dopamine release, if you're suppressing dopamine
release, you are suppressing testosterone levels so much so that I
would wager that a major effect of sleep deprivation on reducing
testosterone and estrogen is not necessarily because of the lack of
sleep per se, it's because usually when people are not getting enough
sleep, they're getting too much light in their eyes in the middle of
the night as well, a study on this has not been completed yet, but
there are two studies published in "Cell" and "Neuron," both Cell
Press journals, excellent journals, showing that viewing bright light
with the eyes in the middle of the circadian night has a detrimental
effect on dopamine, and therefore has a detrimental effect on things
like testosterone and estrogen, so you can't even begin to talk about
supplements and other ways to optimize testosterone, diet and its
effects on testosterone and estrogen and fertility and reproductive
behavior, et cetera, until you get your breathing right, until you get
things like your light-viewing behavior right, so bright light early
in the day and throughout the day is great, view as much bright light,
ideally sunlight, as you can, as much as you safely can, you obviously
don't want to burn your retinas or damage your retinas, so never look
at any light that's so bright it's painful to look at, but getting a
lot of light in your eyes is not just about adjusting your sleep-wake
rhythms, it's also about optimizing your sex steroid hormones, and
avoiding bright light in the middle of the night is not just about not
disrupting your sleep, it's also about optimizing the sex steroid
hormones, and now that you understand a bit of how the sex steroid
hormones work and how powerful they are for reducing anxiety and all
these other effects, this should be straightforward to do, or
hopefully it's inspired you to get your light-viewing behavior and
your breathing behavior correct. In fact, in thinking about tools, for
many people that are suffering from low levels of estrogen if they
want higher levels or low levels of testosterone if they want higher
levels, just getting the breathing and light-viewing behavior, which
will indirectly support sleep behavior, can be a huge and positive
effect on levels of sex steroid hormones.
I can already anticipate that in hearing this, you might wonder
whether or not viewing light is going to, for instance, increase your
testosterone a lot when in fact you want your estrogen increased, or
it's going to increase your estrogen a lot when you want your
testosterone increased, everything I'm describing here is for people,
regardless of chromosomal or gonadal background, so I'm trying to
basically offer all this information in one swoop, but basically, if
you're somebody who naturally has ovaries and has higher levels of
estrogen than testosterone, then viewing bright light early in the
day, because of dopamine's effects, is going to promote more estrogen
and subtle increases in testosterone, whereas if you're somebody who
starts off with more testosterone and lower estrogen, so somebody
presumably who has testes or maybe you're supplementing with
testosterone through other sources for whatever reason, bright-light
viewing is going to increase testosterone and estrogen in parallel,
but you're still going to maintain the ratio of testosterone to
estrogen, in short, you don't have to worry that you're going to
increase the wrong hormone, this is all about optimizing the ratios of
hormones that you already have. Okay, so we've talked about breathing,
we've talked about light, let's talk about a third element that there
seems to be some excitement about lately for other reasons but that
can actually have some pretty profound influences on hormone levels,
and that's heat and cold, so as always, rather than just offer a tool,
I'm going to tell you the underlying science as it relates to
naturally occurring phenomena because, in understanding that and
understanding the mechanism, you're going to be in a far better
position to understand the tools and mechanisms and how you might want
to adjust them for your own life.
So now you understand the relationship between light, day length,
dopamine, and hormone levels, and everyone should realize that
temperature and day length are linked, and I'm sure as I say that,
you're probably thinking, "Oh, of course." In summer, when there's
more sunlight, days are longer, nights are shorter, in general, it
tends to be warmer out, and in winter, when nights are longer, days
are shorter, it tends to be colder out, and in the winter months,
testosterone and estrogen tend to be lower in many animals and in
humans, and in the summer months, because of the role of dopamine in
promoting the sex steroid hormones, when days are longer and it's
warmer, humans tend to make more estrogen and testosterone relative to
the other months of the year. Now, these effects can be somewhat weak
and modulated as opposed to in seasonally breeding animals where
they're really dramatic, okay? But the point is that temperature and
day length and sunlight, those are all intimately related because of
the systems that we evolved in, right? So before we had artificial
light and artificial heating and artificial cooling, our biology
evolved under systems where temperature, day length, and the hormones
were correlated with one another, so nowadays, there's a lot of
interest in using cold as a way to stimulate testosterone, this is
mainly because in the sports community, in particular, in the
bodybuilding community, they are always seeking ways to maximize
testosterone, dihydrotestosterone, keep estrogen to its minimum
required to still have a libido and still have skin elasticity but
also walk around with Saran-wrap skin, then all this kind of extreme
stuff that happens there has led to a recent movement where, believe
it or not, I heard this and I couldn't believe it, I went and checked,
but although I didn't buy them, that on Amazon, you can actually find,
they're literally underwear that have ice packs, so I think they are
ice pack underwear, so that people are making themselves cold at the
level of the gonads in order to try and increase testosterone and
libido, sounds pretty crazy, but believe it or not, that and things
like ice baths and cold showers can have positive effects on the sex
steroid hormones, both testosterone, mainly in males, and estrogen,
mainly in females, and you might say, "Wait, I thought cold "makes the
reproductive axis kind of shut down a bit "or reduces testosterone and
estrogen," but it turns out it's not actually the cold that's having
these effects in people, things like the ice bath, cold showers, cold-
water swims, these ice underwear or whatever they are, can't believe
that these actually exist, but they do exist, what happens is there's
a rebound in vasodilation after cooling, so cooling causes
vasoconstriction, and then after the cooling, there's a rebound
vasodilation and there's more infusion of blood into the gonads.
There's also an effect that's neural, so let me explain how this works
because there are only a few studies on this, none of which looking at
the frozen underwear, but that have looked at cold exposure and levels
of androgens and estrogens, and it's kind of interesting, so you have
to remember that the gonad, the ovaries and the testes are heavily
vascularized. Remember, even at the level of the brain, GnRH,
gonadotropin-releasing hormone, comes from neurons that, believe it or
not, start off in your nose early in development, migrate into the
hypothalamus. I'm not making that up, they started off in your nose
and migrated to the hypothalamus. Those neurons extend processes, we
call them axons, into the pituitary and release GnRH into the
pituitary. There's a lot of vascularization within the pituitary, so
now those hormones, or GnRH, can stimulate follicle-stimulating
hormone, luteinizing hormone, which then are released and travel into
the bloodstream. Then those hormones reach the ovary or testes, and
they have to get into the ovary and testes, and the way they do that
is through the vascular system, and people forget, but the vascular
system and how constricted or dilated vessels are is controlled by
neurons, all right? We discussed this during the discussion about
stress in the stress episode, but it's well-known to neuroscientists
that the best way to shut down neurons is to cool them, so there are a
lot of examples of this in the scientific literature, but most people
aren't aware of it because you're not digging around in the method
section of these papers, but when we want to shut down neurons, we can
do things like inject drugs that will do that, like lidocaine, you
know, the stuff that makes you numb at the dentist, or you can use
different inhibitors, but one of the best ways to do it experimentally
is to just cool neurons, when you make neurons cold, because there's a
temperature dependence of when neurons can be active and when they
can't, the neurons shut down, so the most plausible explanation for
why cold exposure, either through 1 to 10-minute ice bath or cold
shower or the ice underpants thing, would increase testosterone or
increase estrogen is that you're cooling the neurons that control
vasoconstriction and vasodilation and shutting down the entry of
blood, or at least reducing it, and hormones into the gonad, and then
when the gonad and the surrounding area heats up again, you're getting
a rebound hyper-vasodilation that delivers excessive levels of, not
excessive, but increased levels of GnRH and other hormones and
carriers and carrier proteins and so forth that would then stimulate
the gonad to release more testosterone or would stimulate the gonad to
release more estrogen, that's the most plausible explanation I can
come up with, there aren't a lot of studies looking at direct effects
of temperature on the gonad, and it's going to be a difficult study to
carry out in any case because unless it were done in vitro in a dish,
it's very hard to eliminate all the other things like vasoconstriction
and vasodilation, put simply, we don't know whether or not cold and
heat directly affect the production of testosterone and estrogen, we
only know that cold and heat can modulate those, probably through
indirect mechanisms like controlling the amount of blood flow by way
of shutting down or activating the neurons. Now, there's a lot of lore
around heating up the gonads too much, there's actually a whole set of
pseudoscience webpages out there saying, "Well, if you want a girl,
"you should conceive the child at this room temperature, "and if you
want a boy, "you should conceive the child at this room temperature."
I don't think there's really any firm scientific evidence for that,
for either one, but there's some interesting literature about
temperature dependence of production of hormones, and I think that it
probably relates to these mechanisms of vasodilation and neural
control over vasodilation, and of course, excessively high heat is not
good for the testes, for sperm production, or for sperm health, sperm
have all sorts of proteins in the cap, things like pentraxins and
other things that cause them to swim faster when they're expressed
properly and in the right locations, and heat actually alters the
location and the function of a lot of those proteins, they're very
heat sensitive, and so that's why excessive heat is truly not good for
fertility, which may be independent of heat's roles in promoting
estrogen or testosterone. Okay, so now we've talked about breathing,
light, and temperature, we talked about parenthood, we talked about
competition, and we talked about some pheromone effects, now let's
talk about particular forms of exercise and how they modulate the
steroid hormones, and then we're going to talk about various
supplements, both in reference to testosterone and in reference to
estrogen.
So now let's talk about how exercise in its various forms, weight
training, endurance work, weight training to failure, or less intense
weight training can impact testosterone levels, but I want to remind
you that we're talking about testosterone both in males and females,
and based on what you know from earlier in the episode, testosterone
can have numerous positive effects in both males and females provided
they're in optimal range. So if you look on the web, people will say,
"Oh, you know, "testosterone is increased by weight training, "you
want to do these big, heavy compound movements," squats and deadlifts
and chins and things of that sort, but what about the scientific
studies? Like, what's the actual basis for this? Because if you just
take a step back and look at this from the perspective of a scientist,
you'd say, okay, what is a squat? A squat is loading up a bunch of
weights on a bar and then, you know, sitting down, essentially, and
standing up over and over again. What's a deadlift? It's lifting heavy
weights from the ground. Why would that increase testosterone, right?
This is what's often not discussed in the weight training or even the
exercise science community, what would actually stimulate the release
of testosterone from the adrenals and/or testes, and which one is it,
adrenals or testes or both? And that's often not discussed, but as a
neuroscientist, these are the kinds of things we think about because
we think always that genes don't create behavior, immune systems don't
know when to be activated, lungs don't know when to inhale or exhale,
hearts don't know when to beat except for the information that it gets
from neurons, the nervous system controls all of that, and so really
the answer has to be in the neural system that's related to these
particular types of weight-bearing exercises. So when you go into this
literature, it's kind of hard to find real mechanism, you see a lot of
effects, you'll hear things like, androgen receptor content, meaning
testosterone and its derivatives, receptor content following heavy-
resistance exercise, and you'll find some examples that, for instance,
you know, they do muscle biopsies, they can actually see receptor
increases, looking at either high-volume or low-volume really intense
exercise, and you can find a lot of that but not a lot of mechanism
about how the nervous system would do this, and the reason you'd want
to know how it can do it is that you could potentially build better
protocols or figure out exactly what about these movements is
triggering increases in androgen receptors and testosterone. So what's
interesting is when you start digging into the more mechanistic
studies, what you find is that heavy weight training, so this is
weight training where the sets are done with anywhere from kind of one
to eight rep range, and this translates differently depending on ratio
of muscle fiber type and so forth, but where basically people are
working at anywhere from like, 70% to 95% of their maximum, or
sometimes even going right down to their one-repetition maximum,
really kind of max effort, what you find is that using the nervous
system in a way in which they're moving heavy loads, so that I would
translate to recruitment of high-threshold motor units, for you muscle
physiologists, and there's a rule in muscle physiology about the
neuron recruitment for moving muscles where you basically use the
minimum number of motor units of neurons to activate muscle as you
possibly can, as loads increase, you have to recruit more and more
neurons, you always hear about recruiting muscle fibers, but really,
it's recruiting more neurons to recruit more muscle fibers, and what
you find is that heavy weight training, but not weight training to
failure where completion of a repetition is impossible, leads to the
greatest increases in testosterone. Now, I'm sure there are a bunch of
exercise jockeys out there that are going to come at me with a bunch
of things where, oh, yeah, but high volume and this, and training to
failure and that, sure, if you're willing to kind of put things side
by side, adjust for exogenous testosterone treatment and all the rest,
which was done in these studies, what you find in general is that
weight training with heavy loads, so anywhere from one-rep maximum to
somewhere in the six to eight repetition range, in males or females,
increases testosterone significantly, and it does it for about a day,
sometimes up to 48 hours, and the studies that I found which seem to
hold the most rigor or weight based on where they're published as
opposed to being published in the journal of "Never Heard of It,"
they're published in good-quality exercise physiology journals, for
instance, the paper by Ratamess, R-A-T-A-M-E-S-S et al., which was
published in 2005, which talks about modulations in androgen receptor
content after heavy resistance exercise, looks at going to failure and
not to failure, the work of Izquierdo et al. published in 2006,
"Differential Effects of Strength Training "Leading to Failure Versus
Not Failure "on Hormonal Responses, Strength, and Power Gains," you
know, there are a lot of studies here and I will certainly put the
links to these in the caption, many of these actually include Duncan
French, who runs the UFC training center who I've had the privilege of
meeting and discussing some of this with before, as well as other
authors, of course, but they all point to the fact that there's
something about the engagement of the neurons that recruit high-
threshold motor units in muscle when moving heavy loads, but not to
failure, that has to provide some sort of feedback signal, either to
the gonad to produce more testosterone, or is increasing the activity
of receptors in the body. Now, why do I say that? Well, this is the
puzzle, right? How is it that a particular movement, just like how is
it that interacting with your child, is increasing or decreasing
testosterone? This is the kind of fundamental question at the
mechanistic level, and we answered the question for child-rearing, it
has probably something to do with smell and pheromones, although I'm
sure there are other cues as well, but there's clearly a influence of
hard work at the neural level and then at the muscular level for
increasing testosterone, and there's also clearly an effect of working
too hard and presumably increasing cortisol too much, although I'm
speculating there, in terms of reducing testosterone, and so the
reason we're getting nitty-gritty about this is because ultimately,
we'd really like to understand, what are the optimal protocols? You
know, out there in the literature, you hear, move heavy objects to
increase testosterone, some of that will be converted to the more
powerful androgen, DHT, by 5-alpha reductase et cetera, but we really
don't understand yet how these particular behaviors increase
testosterone and whether or not it's doing that by modulating the
receptors or it's modulating testosterone release directly,
presumably, testosterone release directly and sensitivity of the
receptors, that what most of the muscle physiology studies that I was
able to find point to, but this basically boils down to a particular
set of protocols where if you want to increase testosterone, for
whatever reason, that weight training with heavy loads but not to
failure seems to be the best-supported, at least scientifically
supported, solution to that, now, it may not raise your testosterone
levels as high as you want, but it's definitely taking things in the
correct direction. Now, many of you might be endurance athletes or
also enjoy exercise besides heavy-weight-bearing exercise, and there
are several studies exploring whether or not endurance activity can
increase or decrease androgen levels and whether or not you combine
endurance activity and weight training, whether or not that has any
effect if you do the endurance activity first or second, and the
takeaway from all of this was that endurance activity, if performed
first, leads to decreases in testosterone during the weight training
session as compared to the same weight training session done first
followed by endurance activity, in other words, if you want to
optimize testosterone levels, it seems to be the case that weight
training first and doing cardio-type endurance activity afterward is
the right order of business.
Now, when these are done on separate days, it doesn't seem to have an
effect, they showed no statistical interaction, but it seems that if
you're going to do these in the same workout episode that it's move
heavy loads first, then do cardiovascular exercise, so there's a
little bit of data looking specifically at how endurance exercise
impacts testosterone and its derivatives, and it's very clear that
high-intensity interval training, sprinting et cetera, which somewhat
mimics the neural activity that occurs while moving heavy weight
loads, is going to increase testosterone and there's ample evidence
for that in the literature, and that endurance exercise that extends
beyond 75 minutes is going to start to lead to reductions in
testosterone, presumably by increases in cortisol, but of course, the
intensity of the exercise is going to be important too, you know, I
don't think anyone really believes that hiking for three hours is
going to reduce your testosterone, whereas I think if one were to go
out and run hard for three hours that you can imagine there'd be
reductions in testosterone by way of increases in cortisol, and so
while this area certainly needs more research, it's pretty clear that
limiting the endurance exercise to 75 minutes or less, not making it
too intense, is one way to keep cortisol from going through the roof,
but I've talked on previous episodes, and there are a lot of others
who have talked out there about how to clamp cortisol, how to keep
cortisol more reduced, this is also one of the reasons why, you can
imagine, that various individuals, either for competition or just for
their own purposes, rely on testosterone therapy, exogenous
testosterone, not just for weight training, but for endurance
exercise, so this is one of the reasons why every once in a while,
professional cyclists will get popped for performance-enhancing drugs,
meaning they'll get caught, and it's not just that they're increasing
red blood cells through EPO and things of that sort, oftentimes
they're also taking testosterone not because they want to be large or
have massively hypertrophied muscles, but because they're injecting
testosterone, they don't have to worry about cortisol-induced
reductions in testosterone, and they can just clamp, or keep their
testosterone levels high, not something I'm recommending, but I'm just
justifying the rationale for why an endurance athlete would want to do
that at all.
So now let's switch over to talking about estrogen, so there are many
people who are trying to optimize their estrogen levels, and one of
the places where this shows up a lot and I get a lot of questions
about is menopause, so menopause, as I mentioned earlier, is this
fairly massive reduction in the amount of estrogen that is circulating
in one's blood mainly because the ovary is now depleted of some
estrogen production of its own, the eggs are not being produced,
they've been depleted, et cetera. So menopause is characterized by a
variety of symptoms, and it's multifaceted, probably deserves an
entire episode on its own, but things like hot flashes, things like
mood swings, things like headaches, in particular migraine headaches,
there can be a lot of brain fog, it can be very, very disruptive for
people. Now, you sometimes hear about andropause, which is thought to
be the kind of analog to menopause, but menopause has certain
characteristics that make it a very robust phenomenon for most women,
whereas for men, andropause is going to sometimes happen, sometimes
won't, in fact, without going into the details of the graphs and the
data, it's very clear, as I mentioned earlier, that some men maintain
levels of circulating androgens that are quite high, even as similar
as they were in puberty and their teen years and 20s, well into their
60s, 70s, and 80s if they're optimizing a lot of other things, and
probably genetics plays a role as well, whereas some males won't, but
within the female population, or population of individuals that have
ovaries, there's a very stereotyped and characteristic reduction in
estrogen levels as the number of eggs becomes depleted, and that's
what we think of as menopause. So what are the various things that one
can do for menopause? Well, one of the most common ones is that
physicians will prescribe supplemental estrogen, so this is hormone
therapy where somebody takes either their oral estrogen or they'll use
a patch or a pellet, some way to secrete estradiol into the system,
and that has varying success depending on the individual, some people
respond very well to it, other people really have challenges with it,
and there are a lot of side effects associated with it for some
people, not others, in addition, there's a concern always about
supplementing estrogen when there's a breast cancer background in the
family or there's concern about breast cancer for any reason because a
lot of those cancers are estrogen-dependent, and that's why drugs like
tamoxifen and anastrozole and drugs that block either aromatase or
block, excuse me, estrogen receptors directly were initially
developed, you see them a lot on the internet, again, for all the
sports folks who are trying to increase testosterone, reduce estrogen,
but remember, those drugs were initially developed as ways to prevent
estrogen binding to the estrogen receptor as cancer treatments, so I
want to be very clear and I've said this many times, we always put it
in the caption of each episode, of course, that I'm not a physician,
I'm not an M.D., I don't prescribe anything, I'm a professor and I
profess things, I'm here to translate the scientific literature and
point to what might be some useful avenues for exploration, but this
is just for information purposes, you should definitely talk to your
doctor about anything that I'm talking about now or in any episode,
for that matter. So if you look at the literature on menopause outside
of just standard estrogen therapy, there are some very interesting
compounds out there that have been used and that are supported by
quality peer-reviewed studies, and again, I'll refer you once again to
this amazing website, examine.com, where you can put in essentially
any condition or any supplement, and it will point you to the human
effect matrix, not animal studies, but human studies that have
explored these things. Now, there are a huge variety of them here so I
won't go into all of them, but some of the pro-estrogenic compounds
that have been shown to be powerful in the context of menopause, as
well as other conditions where estrogen is lower than one would like,
include a description in some of the literature, I'll get into this in
a moment, of something like black cohosh, I think that's the correct
pronunciation, it's literally the word black and then C-O-H-O-S-H, and
it's very interesting, there are 13 peer-reviewed studies that have
reached prominence in the kind of commercial landscape where this
substance, black cohosh, has been promoted as a way to increase
estrogen, turns out that the effects are consistent but are fairly
minor, fairly minor increases in estrogen, so it does seem to be a
real effect, it is significant over the placebo effect, but there's
also a significant placebo effect in some of these studies as well, so
what's interesting when you look at these studies is that many of them
were carried out over a period of six-plus months, they're double-
blind studies, et cetera, and almost all of them lead to modest
increases in estrogen and modest decreases in menopause-related
symptoms. Now, a few additional details about these studies, they were
generally carried out on women age 45 to 64, in some cases, they look
specifically at women that were clinically obese or overweight,
although not always, the subject size pools are pretty big, you know,
anywhere from 50 to 87, these are decent size, 132 subjects, et
cetera, so these look to be like quality studies, and they basically
point to the fact that black cohosh can have a modest effect in
improving menopause symptoms. The other one is Panax ginseng, so P-N-
A-A-X ginseng, has been shown to decrease some symptoms associated
with menopause, mostly related to libido, although the other effects
were unreliable. Other things, like maca, which is known to increase
dopamine actually, had minor effects, things like, the names here are
a little hard to pronounce, so forgive me, things like Valeriana
officinalis has shown that there can be some improvement in the hot
flash symptoms and some of the insomnia associated with that, so that
might be worth exploring, again, discuss with your doctor, but these
were both 100-subject plus, age 45 to 64 individuals, double-blind
placebo-controlled studies that showed significant but modest effects.
There was one substance in the gallery of the compounds that was
looked at that turns out to be particularly interesting, and this one
is also particularly difficult to pronounce, and it's Pueraria
mirifica, so I'm going to spell this out for you, it's P-U-E-R-A-R-
I-A, Pueraria, mirifica, M-I-R-I-F-I-C-A, and there are four studies
on this compound that show, in every case, it to be very potent, in
fact, comparable to estrogen therapy, estrogen replacement therapy, in
reducing the symptoms of menopause, so this was pretty striking
because when you go through these studies and you look again that they
seem to be pretty well controlled, as far as I could tell, and they
explored a pretty wide subject pool, and it seems that every single
one of these studies, when looking side by side at Pueraria mirifica,
which is also called, now this is really hard to pronounce, Kwao Krua
Kao, I guess that's the name that they use in various countries, that
it was comparable to estrogen replacement therapy, so I mentioned this
because a lot of people contacted me and said, "What about the
insomnia in menopause? "What about the headaches in menopause?" Now,
I'm not suggesting you run out and immediately start taking any of
these compounds, please talk to your doctor, you know, any hormone-
related compound is a serious consideration because of the
relationship to breast cancers, but just in general, these compounds
are, estrogen and testosterone, are exceedingly powerful in terms of
controlling our mental and physical states, and so you want to
approach them with caution, but I thought that that one in particular
was interesting and for which there are quite a few PubMed-documented,
peer-reviewed studies in quality journals. Okay, so now let's talk
about the role of specific compounds, some of which, many of which can
be taken in supplementation form or extracted from diet and nutrition
in order to optimize sex steroid hormones, and again, I just want to
emphasize that I'm not suggesting anyone take anything or stop taking
anything, this is purely for informational purposes, but some of the
data on these is quite striking and impressive.
It's very clear that certain collections of nutrients are useful for
promoting testosterone and estrogen production in their proper ratios,
and those things are what I would call the sort of usual suspects,
vitamin D, which is important for so many biological functions,
including endocrine functions, zinc, magnesium, et cetera, and if you
want to look into this more deeply and you want to understand exactly
what the negative effects are of not having sufficient zinc and
magnesium, and what those levels might actually be, there's a paper
that's available, you can go on PubMed, I can't pronounce this last
name, I'm sorry, it looks to me like Wrzosek, but it's W-R-Z-O-S-E-K,
I hope I didn't butcher that too badly, Wrzosek et al. 2020 in
"Endocrinology and Metabolism Review," so this is a recent paper in a
good, peer-reviewed journal that talks mainly about how the
hypothalamic-pituitary-adrenal axis and the sex steroid hormones are
negatively impacted by deficiencies in magnesium, deficiencies in
vitamin D, and deficiencies in zinc, however, that doesn't point to
the levels that one should take in order to optimize, so it doesn't
say take X amount of zinc or X amount of magnesium or X amount of
vitamin D, for that information, because it's so context-dependent and
individual-dependent, I highly recommend you go to examine.com, you
can put in zinc or magnesium or vitamin D, and they will give you
ranges of dosages that are supported by specific studies, again, that
information is completely free to you, and it's very useful in
figuring that out. I personally have supplemented with zinc,
magnesium, and vitamin D for years, but many other people do that as
well, and the question is always, how much? And that's why I'm a
proponent of getting blood work done because that's how you know
whether or not your androgen levels, as well as things like vitamin D
levels, et cetera, are sufficiently high, so the takeaway from these
studies looking at what deficiencies cause in terms of deficits in
testosterone and estrogen really point in the direction of, make sure
you're getting adequate zinc, magnesium, and D3 unless you want these
steroid hormone levels to be reduced for whatever reason. One of the
things that's been shown time and time again to have very negative
effects on sex steroid hormones, testosterone mainly men, estrogen
mainly in women, is opioids.
There's this whole issue, of course, of the opioid epidemic, it's
deserving of an entire episode, we are going to talk about that with
experts in addiction and people that treat pain and so forth, but the
opioids dramatically reduce levels of testosterone and estrogen, and
they do that mainly by disrupting the receptors on gonadotropin-
releasing hormone neurons, these neurons within the hypothalamus that
communicate to the pituitary, and in fact, people that take large
amounts of opioids, or even take low levels of opioids for long
periods of time, will develop all sorts of endocrine syndromes, that's
been shown over and over again, gynecomastia, or male breast
development in males, disruptions to the ovary in females, it's really
a quite terrible situation, so excessive opioids are very problematic
for sex steroid hormones, I don't think anyone will have any trouble
finding any literature on that, you can just go into PubMed, you can
put opioids, testosterone, or opioids, estrogen, but the major effect
is actually way up in the hypothalamus to shut down the production of
GnRH, the very hormone that stimulates testosterone and estrogen
release. Now, there's an entire industry devoted to supplements and
various things that people can take to increase testosterone, some of
which have scientific data to support them, some of which do not, and
some of which have anecdotal support and some of which do not.
This ranges so broadly, I mean, things like the material off deer
antlers, which is high in, supposedly, IGF1, which is in the growth
hormone pathway, all the way to actual consumption of bull testes, you
can go on Amazon right now, I certainly don't suggest that you do
this, and you can actually buy ground up testes from cows, and you can
consume those, now, a lot of that's going to be broken down in the
gut, I'm certainly not suggesting you do that, but just the point out
this is a huge and vast literature, and it actually dates back
hundreds of years even though testosterone wasn't discovered that long
ago as a specific hormone molecule and characterized and then
resynthesized, it has a huge industry because of the powerful effects
that it has, likewise with estrogen, the development of the birth
control pill was only made possible by understanding the structure of
estrogen and estradiol, and we're going to talk all about birth
control and how it works and its influence on various other pathways
in a future episode, but there are these supplement compounds that are
supported by the scientific literature in terms of their ability to
adjust androgens, things like testosterone and dihydrotestosterone.
One of the ones that has really good evidence for it is creatine, it's
very clear that something about creatine, although the mechanism isn't
exactly clear, either increases 5-alpha reductase or makes the
testosterone molecule more susceptible to certain enzymatic reactions
that leads to increases in DHT, DHT, dihydrotestosterone, as I
mentioned in the previous episode, has this dramatic role in creating
a kind of masculinization of the brain prenatally, it also defines the
primary sex characteristic of the growth of the penis, et cetera, and
beyond infancy and early childhood and later in life, it has powerful
effects in creating balding, in beard growth, et cetera, and it has a
much higher affinity for the androgen receptor than does testosterone,
so creatine can increase DHT, which means that if you take creatine
and you're very DHT-susceptible, then you might experience some hair
loss, this has been heavily debated, does creatine cause baldness?
It's going to depend, it's going to depend on how much 5-alpha
reductase you have and how prone to hair loss you are, some people can
take creatine without any problem in terms of hair loss, some people
cannot, they start losing their hair to levels that, at least for
them, aren't comfortable. There are a few other things that can
increase testosterone and it has to do with the way that testosterone
exists in its free and its bound form, so testosterone, the molecule
is kind of total testosterone, that's usually what's measured, this is
the kind of levels that are typically thrown around of anywhere from
300 to 900 being the kind of natural range, and then
supraphysiological, getting up into 1,200, 1,600 range, but
testosterone isn't just roaming around free in the blood, at least
most of it isn't, most of it is bound to either sex hormone binding
globulin, SHBG, or to albumin, they're needed as transporters to get
testosterone into cells so that testosterone can have its effects on
gene expression as well as other pathways within the cells, so people
talk about that the level of free testosterone is really what's
important and that you want to optimize free testosterone, that's a
little bit of a tricky statement, that's kind of like, it's true, and
yet, it's not really reflective of a thorough understanding of how
these binding globulins work, remember, these binding globulins aren't
there to soak up all your testosterone just to make it hard for you to
free up testosterone and you know, make gains in the gym or whatever
it is, or have increases in libido, they're there to actually
transport testosterone to specific tissues, to shuttle them to
specific tissues and to set the rate of bound and unbound testosterone
so that's it's not all unbound at once, and you know, it's always
interesting to look in the literature and see how everyone wants to
free up their testosterone so that it can work, but sex hormone
binding globulin can bind up too much testosterone to the point where
it's having negative effects on libido or on muscle growth and fat
loss and things of that sort, this is true in males and females, or it
can be doing exactly what it's supposed to do, which is shuttling
testosterone to the proper tissues and organs where it has all these
effects, including the brain.
So there are supplements, in particular, tongkat ali, which is, it has
this other name, it's something called tongkat ali, sometimes it's
called, and forgive me that it's hard to pronounce, but Eurycoma
longifolia Jack, they always seem to have these names that kind of
allude to androgenic features, like I don't know why, longifolia Jack,
I don't know, I think it's kind of obvious why that sounds sort of
androgenic. This has been shown in several studies, and you can find
these on examine.com, or you can go to PubMed if you like, I've looked
at these, that it does seem to have some pro-fertility, pro-free
testosterone, and subtle aphrodisiac effects, it does also seem to be
a slight anti-estrogen, so the reports of this are, people take this
anywhere from 400 to 800 milligrams a day, again, I'm not suggesting
you do that, but that's kind of what's out there, and there is some
decent scientific literature to support the fact that it liberates
some of the bound testosterone and allows more free testosterone to be
available, some of the reported quote-unquote side effects are things
like excessive alertness and insomnia if it's taken too late in the
day and so forth, but I encourage you to explore that further if
that's, if increasing free testosterone is something that you're
interested in doing.
Examine.com includes a lot of other things that can increase
testosterone, one of the things that's been purported to free up
testosterone in the blood are things like nettles, stinging nettles,
although I should point out that the literature points to stinging
nettle also having some fairly potent effects on the prostate and on
the liver, and so it might be a tricky molecule and maybe not an
attractive one for people to take. So we talked about creatine, we
talked about tongkat ali, it's clear that boron, which is really
interesting, believe it or not, I think boron comes from, I think
these were like, meteors that landed on Earth and now they extract
boron, it's one of these crazy stories that, when you look at it, you
go like, "How could that possibly be?" but there's actually, that's
how it works, that boron, there's some scientific support for it
freeing up more testosterone, and again, freeing up testosterone may
be exactly what you want, I just don't think that we should demonize
these carrier proteins like albumin and SHBG, in fact, albumin is very
important for testosterone to be able to make it into the brain to
have some of the pro-androgenic effects on the cognitive effects of
testosterone because in both males and females, testosterone can shift
these behaviors, like mate-seeking, reductions in anxiety, and so
forth, that we talked about before, only by making it into the brain,
and there is this thing called the blood-brain barrier, which is
fascinating and deserving of an entire episode also, and getting
molecules across the blood-brain barrier, even if they're sex steroid
hormones, which are lipophilic and can pass through cell membranes,
requires carriers, and those carriers often are bound to or include
albumin, and so it's not the goal to free up all your testosterone,
but getting free testosterone into a range that works for your
particular goals and needs is an attractive one, and that's why we're
discussing these particular tools. The amounts of boron that people
take, and you can find this, again, on PubMed or Examine, but people
take a couple grams of it a day, I'm not aware of any specific side
effects, but you always, always, always want to examine for the
particular side effects and people with different backgrounds and
conditions, as we talked about for menopause and estrogen, have to be
careful because when you're starting to modulate hormones, you're
starting to modulate not just the tissues that thrive on binding of
those hormones, but remember, the reason why there's so much breast
cancer and there's a reason why there's so much testicular cancer is
that any tissue that undergoes rapid reproduction of particular cells,
so there's a lot of reproduction of cells in shedding of uterine
lining and the reproduction of cells and eggs in the ovary, and in the
testes, there's the production of Leydig and sertoli cells, and
there's this kind of ongoing production of sperm, that's why those
tissues are particularly vulnerable to the development of cancers, and
many of those cancers are androgen-sensitive, that's why one of the
major treatments for prostate overgrowth or prostate cancer is to give
anti-androgenic drugs, okay?
It's not just to shut down all things related to being androgenized,
it's really about trying to prevent testosterone from encouraging
growth of tumors, so I want to really emphasize the caution there
because it's easy when thinking about optimizing estrogen and
testosterone to just think, oh, more is better, more is definitely not
better, and it's not just because they can aromatize or convert into
other things, it's because cancers, or any tissue that has a lot of
turnover of cells, is going to thrive on androgen, anything that
promotes growth is going to thrive on estrogen, remember, brain tissue
doesn't turn over that much, there isn't really much production of new
neurons, brain cancers happen but they're kind of rare, and when they
do happen, they tend to be glial cells, which have a lot of
proliferation, glial cells can proliferate, adult neurons don't create
more of themselves, they don't create more neurons, in general, except
in a few places in the brain and body, so any tissue that recycles
itself is prone to cancers, and those tissues thrive on androgens and
estrogens to create more tumor, so you have to be careful anytime
you're modulating hormones, especially androgens and estrogens, and in
my scouring of the literature and looking at kind of what's out there
and what people are talking about, and I also mean in the scientific
literature, one of the things that is new to me, anyway, probably not
new to a lot of the gym rats out there, or the people that spend a lot
of time on YouTube videos talking about androgens, are these, forgive
me for butchering the name again, are these ecdysteroids, so
ecdysteroids are molecules that come from things like spinach, believe
it or not, that have a lot of similarity to the cholesterol molecule,
the one that's being discussed a lot out there right now is something
called turkesterone, I wish I knew why it was called turkesterone,
someone tell me why it's called turkesterone, does it have anything to
do with turkeys?
I don't know why it's called turkesterone, perhaps someone will know.
In any case, these ecdysteroids are similar enough to cholesterol, and
remember, cholesterol is the precursor to testosterone, cortisol, and
estrogen, and it appears that some of these ecdysteroids do have
bioavailability, or their metabolites are bioavailable, and this was
something that, for many years, people talked about whether or not
insect hormones or hormones from other species could actually be used
by humans or whether or not it would have any effect at all, and it's
pretty clear based on a study that I was able to find, there's a paper
that came out in 2019, it's a comparative study in the "Archives of
Toxicology," this is Isenmann et al., I-S-E-N-M-A-N-N et al., that
talks about the ecdysteroids and it was given in conjunction with
strength training or no strength training, this was a 10-week
intervention, and their conclusion is that these ecdysteroids had a
fairly significant, above placebo controls, increases in muscle mass,
strength, hypertrophy effects, all the sorts of things that one would
expect with increases in androgen, their conclusion of this study is
not my conclusion, although I may or may not agree with them, this
isn't about my opinions, it's just, I want to be clear, these are
their words, not mine, but they say that, in their words, quote, "Our
results strongly suggest "the inclusion of ecdysteroid "in the list of
prohibited substances." So they're saying these things are so powerful
that they should be on the list of banned substances, which might be
upsetting to some, or some of you might be thinking, well, who cares?
The whole issue of augmenting hormones in sports is a very interesting
issue, in fact, if you just want a little anecdote about that, I can't
reveal names here, of course, but what I learned recently was very
surprising to me which is that many athletes in pro sports are taking
testosterone, and they are able to do that legally not just because
it's available by prescription, but they are allowed to do that under
the rules of their sport in the fine print that no one, including me,
had ever seen, if they've had an injury, so if athletes are injured,
then it opens up the door for certain forms of testosterone
augmentation and other types of augmentations that are not available
to them if they're not injured, which always makes me wonder now when
I see them getting injured whether or not that's an attempt to get
some of the support because there's absolutely no question that
estrogens and testosterones modulate gene expression, modulate
strength, modulate the way the brain works, modulates our relationship
to effort and anxiety, et cetera, and while we're talking about
supplementation, the effects of supplementation, I would say, in some
individuals can be quite dramatic, but they're always, always, always,
except in extreme cases, going to be far subtler, excuse me, far more
subtle, to use the proper English, far more subtle than would be, for
instance, just in injecting testosterone or injecting estrogen, et
cetera, so I think we should just be honest and upfront about that. So
thus far in terms of talking about optimizing hormones and in the
discussion of supplementation, I haven't really talked about things
that actually affect the brain directly, that increase the pituitary
output and things of that sort, we've mainly been talking about things
that free up testosterone or that increase estrogen at the level of
the periphery, but if you remember way back to the beginning of this
episode, hormones are made in different locations in the body and
there are hormones that promote the release and the production of
hormones from other tissues in the body, and one of the main hormones
for that is luteinizing hormone, luteinizing hormone, again, comes
from the pituitary, circulates and either goes to the ovary to promote
various aspects of egg maturation as well as production of estrogen,
and to the testes to promote testosterone and sperm production, and
the prescription version of increasing luteinizing hormone is
something called hCG, or human chorionic gonadotropin, which has been
synthesized and is now available as a prescription drug, it's taken in
various contexts for increasing fertility both by males and by
females, it can increase, for all the reasons that now make sense, it
can increase sperm production, it can produce ovulation frequency, it
can produce the number of eggs, even, that are deployed in a given
ovulation, although that's not always a good thing, it basically is
pro-fertility, pro-testosterone, pro-estrogen depending on your
background, and what's interesting is hCG was initially synthesized,
collected and synthesized from pregnant women's urine, and believe it
or not, before it was synthetically made and sold as a prescription
drug, there was actually a black market for pregnant women's urine
where people would buy the urine, I don't know, I'm guessing that they
probably just consumed it, which is weird, but in any case, human
chorionic gonadotropin is now available as a prescription drug and
it's one of the things that many people use to increase testosterone
or estrogen for increasing fertility, in some cases I think it's used
to increase sports performance or when people have shut down their
gonads for whatever reason because of excessive hormone therapies or
they have some sort of, sometimes there are actually lesions to the
pituitary, sometimes people have a tumor in the pituitary, it's
actually not common, but among brain tumors and neural tumors, it's
one of the more common ones, and then you get deficiencies in LH and
FSH, and so people will take hCG to stimulate the gonads, so there are
a variety of reasons why these drugs were created, but there are
certain supplements, not many, that apparently can increase
luteinizing hormone and thereby can increase testosterone and
estrogen, and one of the more well-documented one is Fadogia agrestis,
that's F-A-D-O-G-I-A, separate word, A-G-R-E-S-T-I-S, which, at least
according to the literature that I was able to find, can increase
levels of luteinizing hormone and thereby levels of testosterone or
levels of estrogen, and again, if an individual were to take Fadogia
agrestis, what they would probably find is that testosterone and
estrogen would increase in anyone of any chromosomal or gonadal
background, but remember, it's the ratio of both, if someone has low
estrogen and high testosterone, let's say they have testes just by way
of example, then both of those would be expected to increase, and if
someone has high estrogen and low testosterone, and let's just say has
ovaries, then both of those would increase by taking Fadogia agrestis.
The side effect profile of Fadogia agrestis hasn't really been
documented, so it's a little unclear, I just want to emphasize that
anytime someone's going to start taking supplements, or modifying sex
steroid hormones, getting blood work done is extremely important for
safety reasons, and also just to know whether or not things are
working, and because all of these things are subject to negative
feedback, talked about this previously on a previous episode, but if
testosterone goes high, or too high, it can feed back and shut down
luteinizing hormone, which will then shut down further testosterone
production, likewise, if estrogens are going too high or they're going
too high at various phases of the cycle, that can start to throw off
various other hormones, including FSH, progesterone, LH, the menstrual
cycle itself is a just absolutely exquisite balance of feedback of
luteinizing hormone kept low and constant, at least for the first 14
days of the cycle, then mid cycle, there's a peak, and that's
typically when ovulation occurs, that's why pregnancy is most likely
during the middle of the 28-day cycle, FSH kind of goes up and then
down across the first 14 days, so taking anything or really modifying
one's estrogens or testosterone on that background of the menstrual
cycle is really going to disrupt the way those things interact, and
it's just such an exquisite feedback loop, so I'm not saying don't do
that, but you definitely want to be aware of what you're doing, and
blood draws are one way to do that, monitoring cycles for ovulating
females is another way to do that, and in males, having a good window
into what's going on with testosterone, DHT, aromatase, estradiol, LH,
et cetera, is just vital, and it's really part and parcel with the
practice of thinking about optimizing these incredible things that we
call sex steroid hormones, estrogen and testosterone and their
derivatives. The list of supplements and molecules that can adjust
estrogen and testosterone is vast, and I only touched on a few of
these, I really tried to emphasize the ones for which there are human
studies or that have mostly human studies, or maybe even just one
human study, there are other things out there for which there are
scientific data, things like Bulbine natalensis, which definitely has
support for increasing testosterone but all the studies were in rats,
I think there is some evidence in humans but the evidence mainly comes
in the form of what we call sponsored research, so companies paying
for research, which is different than independent research by people
who are not biased in terms of the outcome, and the reason I didn't
throw out things like Bulbine natalensis is they seem to have liver
toxicity similar to high levels of anabolic exogenous steroids,
there's some problems associated with them that make them, you know,
important to think about if you're curious about this area and the
endocrinology, but also somewhat precarious, and you know, that's one
category, so stuff that doesn't have a lot of evidence in humans,
might actually be dangerous, the other category of things that has
been shown to improve levels of, or increase, I should say, I don't
want to say improve because it's up to you whether or not you want to
increase or decrease estrogen and testosterone, that's highly
individual, how could I know, are the things that are kind of
housekeeping for production of estrogen and testosterone, things like
magnesium, things like D3, things like zinc, you know, those are the
things that are going to create an overall milieu of opportunity to
produce normal endogenous levels rather than increasing endogenous
levels further, and so I really want to highlight that there's a
difference between taking something to create a kind of backdrop of
general support and taking something that's going to create a big
inflection in the levels of a given hormone.
So once again, we covered a tremendous amount of information, we
covered some basic science of hormones and pheromones, estrogen and
testosterone and their derivatives, we talked about supplementation
and behaviors, competition and parenting, and how all these things
interact, and I hope that you'll come away from this with a deeper
mechanistic understanding of how the brain and body are interacting to
control the output and the ways in which these incredible things that
we call sex steroid hormones work and influence us, I hope you'll also
come away with some ideas of things that you can do, in particular,
behavioral practices that can improve sleep and your relationship to
light, et cetera, because those things really set the foundation not
just for healthy steroid hormone output, but for all sorts of health
effects and for both the psychology and the biology of your nervous
system, so I'm sure there'll be many questions, there are many things
that I couldn't get to today, I do try and limit these episodes to
about 90 minutes, which is the optimal ultradian cycle for learning,
it's a lot of information, but we've timestamped everything for you,
so feel free to look over it in parts or circle back where you might
want deeper understanding, and please put your questions in the
comments section below, please put suggestions for future episodes and
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look at those and we do use them to inform the content for subsequent
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that will, of course, include both mechanisms and tools as well, and
as always, thank you for your interest in science. [upbeat music]
**Note: Future episodes will focus on the science of prescription
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HubermanLab #Testosterone #Estrogen
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