Huberman Lab - How to Build Strength, Muscle Size & Endurance | Dr. Andy Galpin
Episode Date: March 28, 2022In this episode, I discuss fundamental principles of strength and hypertrophy training and building endurance, along with the mechanisms underlying them. Joining me is Dr. Andy Galpin, Professor of Ki...nesiology at California State University, Fullerton, and one of the foremost experts in the world on the science and application of methods to increase strength, hypertrophy, and endurance performance. We review specific protocols to optimize training and recovery, and also delve into hydration, sleep, nutrition, supplements, and mental tools that can be leveraged to accelerate adaptations leading to enhanced strength, muscle growth, and/or endurance. For the full show notes, visit hubermanlab.com. Thank you to our sponsors AG1: https://athleticgreens.com/huberman LMNT: https://drinklmnt.com/hubermanlab Waking Up: https://wakingup.com/huberman Momentous: https://livemomentous.com/huberman Timestamps (00:00:00) Dr. Andy Galpin, Strength & Endurance Training (00:03:23) Sponsors: AG1, LMNT (00:08:20) Adaptations of Exercise, Progressive Overload (00:14:40) Modifiable Variables, One-Rep Max, Muscle Soreness (00:27:30) Modifiable Variables of Strength Training, Supersets (00:43:50) How to Select Training Frequency: Strength vs. Hypertrophy (00:58:45) Hypertrophy Training, Repetition Ranges, Blood Flow Restriction (01:08:50) Tools: Protocols for Strength Training, the 3 by 5 Concept (01:10:48) Mind-Muscle Connection (01:16:16) Mental Awareness (01:27:57) Breathing Tools for Resistance Training & Post-Training (01:37:25) Endurance Training & Combining with Strength (01:51:20) Tools: Protocols for Endurance Training (02:08:15) Muscular Endurance, Fast vs. Slow Twitch Muscle (02:16:35) Hydration & the Galpin Equation, Sodium, Fasting (02:35:57) Cold Exposure & Training (02:43:15) Heat Exposure & Training (02:53:47) Recovery (03:04:02) Tool: Sodium Bicarbonate (03:17:26) Tool: Creatine Monohydrate (03:20:08) Absolute Rest (03:29:08) Zero-Cost Support, YouTube Feedback, Spotify, Apple Reviews, Sponsors, Supplements, Instagram, Twitter Disclaimer Learn more about your ad choices. Visit megaphone.fm/adchoices
Transcript
Discussion (0)
Welcome to the Huberman Lab podcast,
where we discuss science and science-based tools
for everyday life.
I'm Andrew Huberman and I'm a professor of neurobiology
and ophthalmology at Stanford School of Medicine.
Today my guest is Dr. Andy Galpin.
Dr. Galpin is a full and tenured professor
in the Department of Kinesiology
at California State University in Fullerton.
He is also a world expert in all things
exercise science and kinesiology.
Today you are going to hear
what is essentially a masterclass in how to build fitness,
no matter what level of fitness you happen to have.
He talks about how to build endurance
and the multiple types of endurance.
He talks about how to build strength and hypertrophy,
which is the growth of muscle fibers.
So if you're seeking to get stronger
or build bigger muscles or build endurance
or all of those things,
today you're going to learn how.
You're also going to learn how to build flexibility,
how to hydrate properly for exercise,
and we'll also talk about nutrition and supplementation.
What makes Dr. Galpin so unique
is his ability to span all levels of exercise science.
He has the ability to clearly communicate
the sets and repetition schemes that one would wanna follow,
for instance to build more strength
or to build larger muscles.
He also clearly describes exactly how to train
if you want to build more endurance
or enhance cardiovascular function.
What's highly unique about Dr. Galpin
and the information he teaches
and the way he communicates that information
is that he can take specific
recommendations of how recreational exercisers or even professional athletes ought to train
for their specific goals and link that to specific mechanisms, that is the specific changes
that need to occur in the nervous system and in muscle fibers and indeed right down to the genetics
of individual cells in your brain and body in order for those exercise adaptations to occur.
It's truly rare to find somebody that can span so many different levels of analyses and
who is able to communicate all those levels of understanding in such a clear and
an actionable way.
Indeed, Dr. Galpin is one of just a handful of people
to which I and many others look
when they want to make sure that the information
that they're getting about exercise
is gleaned from quality peer reviewed studies,
hands-on experience with a wide variety of research subjects,
meaning everyday people all the way up to professional athletes
in a wide variety of sports.
So it's no surprise that he's not only one of the most knowledgeable,
but also the most trusted voices in exercise science.
Dr. Galpin is also an avid communicator
zero cost to consumer information about exercise science.
You can find him on Instagram at Dr. Andy Galpin
and also on Twitter at Dr. Andy Galpin.
Both places he provides terrific information
about recent studies, both from his laboratory
and from other laboratories,
more in-depth protocols of the sort that you'll hear about today.
So if you're not already following him,
be sure to do so.
He provides only the best information.
He's extremely nuanced and precise
and clear in delivering that information.
I'm certain that by the end,
end of today's conversation, you'll come away
with a tremendous amount of new knowledge
that you can devote to your exercise pursuits.
Before we begin, I'd like to emphasize
that this podcast is separate from my teaching
and research roles at Stanford.
It is, however, part of my desire and effort
to bring zero cost to consumer information
about science and science related tools
to the general public.
In keeping with that theme,
I'd like to thank the sponsors of today's podcast.
Our first sponsor is Athletic Greens.
Athletic Greens is an all in one vitamin mineral probiotic drink.
I've been taking Athletic Greens since 2012,
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The reason I started taking Athletic Greens
and the reason I still take Athletic Greens once or twice a day
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It makes up for any deficiencies that I might have.
In addition, it has probiotics,
which are vital for microbiome health.
I've done a couple of episodes now on the so-called gut microbiome
and the ways in which the microbiome interacts
with your immune system, with your brain,
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If you'd like to try Athletic Greens,
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Again, go to athletic greens.com slash Huberman
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and the year supply of vitamin D3K2.
And now for my discussion with Dr. Andy Galpin.
Welcome, Dr. Professor Andy Galpin.
It's been a long time coming.
We have friends in common,
but this is actually the first time
we've sat down face to face.
Yeah, I'm very excited.
Yeah, there are only a handful meaning
about three or four people who I trust enough in the exercise physiology space that when they speak,
I not only listen, but I modify my protocols. And you are among those three or four people.
So first of all, a debt of gratitude. Thank you. You've greatly shaped the protocols that I use.
And I know there's far more for me and for others to learn. So you're a professor. You teach in
university and you have a tremendous range of levels of exploration. Muscle biopsy, literally,
images down the microscope all the way to training professional athletes and everything in
between. So you are truly an end of one. And just to start us off, I would love to have you
share with us what you think most everybody or even everybody should know about principles
of strength training, principles of endurance training.
and principles of, let's call it, hypertrophy power and the other sort of categories of training.
And this could be very top contour.
But what do you think everybody on planet Earth should know about these categories of personal and athletic development?
Well, that's a great first question.
Holy cow.
I think I'll start it this way.
I tend to think about there's about nine different adaptations you can get from exercise.
Fat loss is not one of those.
It is a byproduct, but that's not really what I'm getting at.
And so we can kind of categorize everything like that.
And what are we can talk about
or what are the concepts that you need to hit within each one?
And then you can have infinite discussion
of the different methodologies, right?
And so that first thing to hit is
the concepts are actually fairly few,
but the methods are many, right?
People have said that in iterations throughout time.
So if you walk from the very beginning,
the first one to think about is what we'll just call skill.
So this is improving anything from, say, a golf swing
to a squatting technique, to run.
And this is just simply moving mechanically how you want your body to move.
I'm just going to globally call that skill.
From there, we're going to get into speed.
So this is moving as fast as possible.
The next one is power.
And power is a function of speed, but it also a function of the next one, which is strength.
So if you actually multiply strength by speed, you get power.
And the reason I'm making this distinction, by the way, is some of these are very close,
and I'm going in a specific order on purpose here.
For example, power is like I just say,
that it's a function of speed and strength.
So if you improve speed,
you've also likely improved power,
but not necessarily, right?
Because it could have come from the force direction either.
So there's carryover,
so like a lot of things that you would do
for the development of strength and power,
they are somewhat similar,
but then there's differences, right?
So things that you would do correctly for power
would really not develop much strength
and vice versa.
So we can get into all these details later.
Once you get past strength,
then the next one kind of down the list
is hypertrophy.
This is muscle size,
growing muscle mass is one way to think about it.
After hypertrophy, you get into these categories
of the next one is,
these are all globally endurance-based issues
and the very first one is called muscular endurance.
So this is your ability to do
how many push-ups can you do in one minute,
you know, things like that.
Past muscular endurance,
you're now into more of an energetic
or even cardiovascular fatigue.
So you've left the local muscle
and you're now into the entire physiological system
and its ability to produce and sustain work.
And we can get into a bunch of differentiations
with endurance, but just to keep it really simple right now,
the very first one, think about this as,
I call this anaerobic power, right?
So this is your ability to produce a lot of work
for, say, 30 seconds to maybe one minute,
kind of two minutes like that.
The next one down then is more closely aligned
to what we'll call your V-O-2 max.
So this is your ability to kind of do the same thing,
but more of a time domain of, say, three to 12 minutes.
So this is going to be a maximum heart rate,
but it's going to be well past just max heart rate.
Then after that, we have what I call long duration endurance.
So this is your ability to sustain work.
The time domain doesn't matter in terms of how fast you're going.
It's how long can you sustain work.
This is 30 plus minutes of no break like that.
So as just an high-level overview,
those are the different things you can target.
And again, some of those cross-stop.
over, and some are actually a little bit contrary to the other ones. So pushing towards one
is maybe going to sacrifice something else. So as an overall start, that's really what we're looking at.
Within all of those, though, they do have similar concepts in terms of there's a handful of things
you have got to do to make all of those things work. And we could talk about as many of those
as you want, but one of them is functionally called progressive overload. So whichever one you're
trying to improve at, if you want to continue to improve, you have to have some method of overload.
And as you well know, you've talked about a lot, adaptation physiologically happens as a
byproduct of stress. So you have to push your system. So if you continue to do, say,
the exact same workout over time, you better not expect much improvement. You can keep maintenance,
but you're not going to be adding additional stress. So in general, you have to have some sort
of progressive overload. And we can talk in detail about what that means for each category. But
this could come from adding more weights. This could come from adding more repetitions. It could come
from doing it more often in the week. It could come from adding complexity to the movement. So going from
say a partial range of motion to a full range of motion or adding other variables. So there's a lot of
different ways to progress, but you have to have some sort of movement forward. So if you have this
kind of routine where you've built Monday, Wednesday, and Saturday or something, and you just do
that infinitely, you're not going to get very far. So that's, I guess, the most
high-level overview of all the things people can go after. And then we can go from whatever direction
you want from there. I'd love to do the deep dive on each one of these for several hours.
But I imagine that over time, we probably will. I'd love to chat about a couple of these in a bit
more depth. So in terms of defining what the progressive overload variables are for these different
categories, maybe we could hit the two most common combination.
of these nine things. The first one being
strength and hypertrophy. And maybe we could lump power
in there. Maybe not.
You're the exercise physiologist. But strength and hypertrophy,
which at least bear some relationship.
And then maybe separately, we could explore
sustained work endurance, this 30 minutes
or longer continuously, because I think many people train
in that regime. And probably
something like V-O-2 max anaerobic as well.
because I know that a number of people now incorporate so-called hit or high-intensity interval training,
I think with the hopes of either shortening their workouts and or gaining some additional cardiovascular benefit.
So if we could start with strength and hypertrophy, I know many people want to be stronger,
they want to grow larger muscles, or at least maintain what they have.
So what are the progressive overload principles that are most effective over time for strength and hypertrophy?
Yeah, okay. So I'll actually go a little,
little step back. With every one of those categories I talked about, you have what we call your
modifiable variables. So this is a very short list of all the things you can modify the different
variables within your workout that can be modified that will change the outcome. Fancy way of saying,
if you do this differently, then you're going to get a different result. So modifiable variables.
The very first one of those is called choice. So this is the exercise choice that you select.
Now, one of, I'm going to go double back here, so I'm kind of doing a little bit of inception.
So follow me here as I'm going up a layer to come down a couple layers.
I have these fundamental laws of strength and conditioning that are kind of like a little bit of a joke.
But progressive over those, one of those laws.
Another one of those laws is your exercises themselves do not determine adaptations.
So here's what I mean.
If you're like, I want to get stronger, you can't select an exercise.
That doesn't determine you getting strong.
If you don't do the exercise correctly,
and I'm not even referring to the technique,
that of course matters.
But if you don't execute it in the right fashion,
then you're not going to get that adaptation.
So if you choose, I want to get stronger,
I'm going to do a bench press.
Well, if you do the wrong set range,
the wrong repetition range, the wrong speed,
you won't get strength,
you maybe get muscular endurance
and very little strength adaptation.
So the exercise selection itself is important,
but it does not determine the outcome adaptation.
So the very first thing that you need to think about
if you're like, I want to get stronger
or add muscle,
is not the exercise choice, right?
It is the application of the exercise.
What are the sets, what are the reps,
what are the rest ranges that you're using?
That's going to be your primary determinant.
Now, some exercises are certainly better
for some adaptations.
For example, a deadlift is probably not a great exercise
to do for long duration endurance.
Like, you could theoretically do 30 straight minutes
of deadlifting, but it's probably not our best choice, right?
It's probably a pretty good choice for strength development,
right?
Because you're going to do a low repetition, high set range.
you could theoretically do
bicep curls for power
but probably not your best choice
single joint isolation movement
is not the best for developing power
or you've ever done a bicep curl
as fast as you possibly can
like that's not going to go well
so in theory any exercise
can produce any adaptation
given the execution
is performed properly
so now that we've understood that a little bit
the exercise itself does not
determine the adaptation
coming within each one of these categories
exercise choice is an important variable because it does lend you to things like what movement
pattern you're in. So in other words, if you want to get stronger and you're thinking,
okay, what exercise do I do? You need to think a little bit about what muscle groups do I want to
use and that's going to be leading you towards the exercise choice. For example, I want to use my
quads more. Okay, fine. Maybe you're going to choose more of a front squat type of variation of
goblin squat. So the bar, the load is in front of you. If you want to,
emphasize maybe more of your hamstrings and glutes, you're going to maybe put a barbell on
your back or do a different one. So the exercise choice is important to the prescription because it's
going to determine a lot of your success. Another kind of simpler way to think about this.
If you're a beginner or moderate to intermediate or maybe you don't have a coach, you probably
want to hedge towards an exercise selection that is a little bit easier technically. So you maybe don't
want to do a barbell back squat. It's actually a pretty complicated movement. Maybe you want to do a
little bit more of, again, a goblet squat, or even use some machines or a split squat, something that's a
little bit simpler because you don't have a coach, you're not a professional athlete. The likelihood of
success is higher and the risk has now gone lower. So the very first variable within all of these is the
exercise choice. The second one is the intensity. And that refers to in this context, not perceived
effort. Like, wow, that was a really intense workout. It is quite literally either a percentage of your
one rep at max or a percentage of your maximum heart rate or V02 max. So for the strength-based things,
you want to think about what's the percentage of the maximum weight I could lift one time. And that's
what we're going to call one rep max. Or it's a percentage of my heart rate, right? So if I tell you to
get on a bike and I want you to do intervals and I want you at 75 percent, I'm typically referring to
75 percent of your max heart rate or VO2 max or something like that. If I tell you to do squats at 75
percent, that means 75 percent of the maximum amount of weight you could lift one time or close.
In terms of determining one rep max, I confess I've never actually taken the one rep max for any exercise,
but I have some internal sense of what that might be or what range it might be.
Is it necessary for people to assess their one repetition maximum before going into these sorts of programs?
No, not at all.
I think a more intuitive way is to take a repetition range.
Well, you can do this a couple different ways.
So there are equations you can run,
and you can just Google these anywhere,
and these are called conversion charts.
And so it says, okay, if I did 75 pounds on my bench press,
and I did it eight times,
you can just run an estimate to say,
okay, you're probably going to be able to bench
about 95 pounds for one rent max or something.
So that's a very easy conversion chart.
So just pick a load that you feel comfortable with,
but it's kind of heavy, but not like crazy heavy,
and do as many repetitions as you can,
what a really good technique,
and then look what that number would be.
So conversion.
Are they safer than doing one repetition maximum?
For the general public who has, again, no coaching, it's safer.
For a professional athlete, it's not any safer, but, or not even a professional athlete,
but a trained person with a coach.
But for most people, yeah, that's a good way to go about it.
You can also just kind of do it with feel in the sense that, say you want to do a set of
five repetitions.
And you do the load and you think, I could have done one or two more.
And then you kind of have an idea of what that number is going to be.
If you think, man, that last one I had to kind of really, really, really get after it,
then maybe just call that number, right?
So you don't have to get overly concerned.
In fact, when we start getting into these number ranges,
you're going to see that they're all ranges.
We're not going to give a specific 95% for one of these exact reasons.
It's not that precise for most of them.
In fact, some of them, like hypertrophy, have enormous ranges that you almost can't miss.
So the intensity in that case doesn't even matter for the most part
because that's not the primary determinant.
Some of these you're going to see intensity is a determinant
and some of these you're going to see volume is the true determinant.
So intensity though is that second one.
Choice was the very first one manipulative variable.
Intensity was the second one.
The third one is what we call volume.
And so this is just how many reps and how many sets are you doing?
So if you're going to do three sets of 10, that volume would be 30.
Five sets of five, that volume is 25.
It's just a simple equation.
How much work are you totally doing?
The next one past that is called rest intervals.
So this is the amount of time you're taking in between typically a set.
Then from there you have progression,
which is what we started to talk about, this progressive overload.
Are you increasing by weight or reps or rest intervals or complexity or whatever?
So all of those things can be changed as a method of progression.
And so maybe you want to go progressing from a single joint.
exercise like a leg extension on a machine and you want to progress by moving to a whole body
movement like a squat that in of itself you don't have to change the load or the reps or the rest that is
a representation of progressive overload and it's probably a pretty good place to start because number one
especially for beginners you want to make sure that the movement pattern is correct don't worry about
intensity don't worry about rep ranges or any of these things you need to learn to move correctly
and you need to give your body some time
to develop some tissue tolerance
so that you're not getting overtly sore.
In general, soreness is a terrible proxy
for exercise quality.
It's a really bad way to estimate
whether it was a good or a bad workout,
especially for people in that beginner to middle
to moderate.
In fact, even the fact for our professional athletes,
we do not use soreness as a metric of a good workout.
It's a really bad idea for a bunch of reasons.
On the same token,
because stress is required for adaptation,
you don't want to leave at the gym and feel like,
I don't really do much.
There has to be there.
So if you think about soreness on a scale of 1 to 10,
you probably want to spend most of your time in like the three.
You mean post-exercise.
Yeah.
In between workouts.
Totally.
And I know we'll talk about recovery extensively later,
but if one body part or set of body parts is sore,
is that an indication that one should stay out of training?
I would imagine the answer is no.
In most cases,
and secondarily to that,
if a particular muscle is sore,
does that mean that muscle is not ready to be trained again?
Yeah, the answer to both those is the same,
which is no, right?
You can certainly train a sore muscle.
You need to, I guess, have a little bit of feel on that, right?
So if you're sore of like, okay, like,
and you're moving around a little bit,
and you're like, man, this is a little bit sore, you can train.
If you're like, I can't sit on the couch without crying
because my glutes are so sore,
like we probably don't need to train again, right?
Does whimpering count as crying?
Yeah. In that particular case, I'd say you've actually gone to a place of detriment
because now you're going to have to skip a training session.
And now you're behind.
So your actual total volume, say across the month, is actually going to be lower because
you went way too hard in those workouts, had to take too many days off in between.
You're going to see that you're going to cover less distance over the course of a month
or six month or even a year.
So you want to walk a pretty fine line
and for most people I would say hedge a little bit
on the side of less sore than more sore
because frequency is very, very important
for almost all these adaptations.
Training frequency.
Which is the last modifiable variable, right?
Frequency, which is how many times per week
are you doing that thing?
So those are
kind of our global things that we can play with.
So when I'm trying to manipulate
and you can get strength versus hypertrophy
or you know what I want like a little bit of both
all those variables are the things that are going through my mind
which one do I need to move in which direction
so that I can get this outcome and not this outcome over here
for example some folks might want to get stronger
but not put muscle mass on some folks are just kind of want both
and that's a lot of the general public I want to get a little stronger
and a little bit more muscle great
but there are instances where people for performance reasons
or for purely personal preference like I don't want to get any more muscle
great but I want to get stronger
Awesome. If you manipulate those variables correctly, you can get exactly that. Very little development
of muscle size and a lot of development and strength. And this is why we continue to break world records
in sports like powerlifting and weight lifting that have weight classes. So there's a top number that we can
hit in terms of body size, but yet we continue to get stronger and faster. So this is very possible
if you understand how to manipulate all those variables. So that being said, we can start off with,
you wanted to go strength. Yeah, strength. And I love that you mention the fact that it is possible to increase
strength without increasing muscle size, at least not dramatically, because I think it's not
just weight class athletes. I know a lot of people who, for aesthetic reasons, they'd like to be
stronger. They're hearing that having strong bones and strong muscles and tendons, it's great for
longevity and for avoiding injury and so many other features of life. And yet they don't want to
fill out progressively larger and larger sizes of clothing. And we can go harder to the mechanisms
on that piece if you want. We can save that and come back to it. Sure. What I'd love to,
Both. What I'd love to know, if we could define some of these modifiable variables in the context of strength. So let's say I were somebody who I come to you and I say, and let's just say for sake of balance here, because she actually does do some weight training. I bring my sister in. I say, me and my sister both want to get stronger.
What modifiable variable should, how should we modify the variables?
Love it. All right. Great. I'm going to do Inception on you one more time.
So one of my other laws, this won't be fast, I promise, of strength and conditioning is in general.
The default is all joints through all range of motion.
So this is important because it's going to answer the very first question on this strength category.
So in general, the ankle should go through the full range of motion, the ankle.
The knee should go through the full range of motion, the knee, the hip, the elbow, etc., etc., right?
Across the workout, not in a single movement.
Well, right.
I would hope.
Unless there's an amazing exercise I haven't heard about it.
Well, there are some exercises that we're going to call more full body.
Think about a full snatch.
Like, you're going to take a lot of your muscles,
a lot of your joints through a lot of the range of motions.
Other ones like in isolation, we call these single joint exercises.
So imagine a bicep curl.
You have one joint in that particular case, the elbow moving,
the shoulder and everything else is pretty much stable.
And this is how we'll differentiate multi-joint from single joint movements.
But yeah, so across, I would even say it doesn't even have to be the day,
but maybe throughout the week.
Try to get every joint through full range of motion.
Now, a couple of quick caveats to that.
I am not advocating using full range of motion
and allowing really bad exercise technique.
So when I say full range of motion, that's the default.
That doesn't mean every single person can do that
for every single exercise.
It means that's where we should be striving to
and that's our starting point.
You're going to see a lot less injury
and a lot more productivity out of your training sessions.
In fact, the science is fairly clear on this one.
strength development as well as hypertry is generally enhanced with a larger range of motion of training
and the mechanisms are like somewhat understood on that so that being said if you have to get into say a bad
position with your say low back the spine is a very good one here in general the spine should say it's
very neutral as what we call it so no no flexion no extension especially in the lumbar region so if you
if you're doing say a deadlift and in order to take your knee through a full range of motion a deadlift
you have to compromise your back position, that's no bueno.
So, caveats there aside, don't kill me.
Like, in good positions always.
And don't kill yourselves, more importantly.
So why that matters is if we walk through strength,
the very first thing I'm going to go through is the exercise selection.
So let's choose an exercise which ideally has a full range of motion or close to it.
That doesn't induce injury for you.
That you can still maintain good neck and low back and position and everything else.
you feel comfortable with so you can feel strong but you don't feel like oh my gosh if you've never
snatched before having you do a snatch for a maximum even you know 75% like it's a terrible idea
you're not going to feel confident it's going to be a train wreck i would rather put you on a machine
bench press so you can go i feel stable i feel safe here and i can just express my strength
so exercise choice in generally in general full range of motion and you want to kind of balance between
the movement areas so this is an upper body press so this is a
is pushing away from you, bench press, things like that.
Upper body pull, pulling an implement towards you, bent row, pull up.
The pressing should be horizontal, so perpendicular to your body, as well as vertical.
So this is lifting a weight over top of your head, lifting away from you.
The pull version is pulling horizontally to you and pulling vertically down, pull up, things like that.
From the lower body, we typically call these hinges.
It's sort of a funny muscle thing that no one's going to laugh at, but like maybe me.
in you here is we'll categorize muscles as our movements, exercises as pushes and pulls,
right? So like a squat tends to be a push because you're pushing away the ground. A deadlift
as a pull because you're pulling the implement up to you. But in reality, every single exercise
is only ever a pull because muscle doesn't push things away. Muscle can only contract and pull on
itself. And so again, super nerdy thing that like most people are like, yeah. And everyone's like,
that's so dumb. No, but I think it's a really important point because it also speaks to something
I think we'll get into later, which is that, you know, posterior chain, anterior chain.
Totally.
And if that's mysterious to people, it'll become clear before long.
Posterior chain, anterior chain makes a lot of sense to me because of the way it's grounded
in the firing of motor neurons, which is ultimately what controls muscles.
So it's also, I think...
You're all the time.
Exactly.
So it also depends on the lens through which one looks at life and exercise.
Of course, my lens is primarily neuroscience.
So...
But I realize that the importance...
I like this idea of pushing...
perpendicular of the body overhead, pulling both toward the body and from overhead.
That just makes really good intuitive sense, especially since a lot of people were just listening
to this and not watching it. So in your minds, folks, you can think about pushing away like a punch
or overhead, like lifting something overhead and then pulling toward your midline, or toward
your body rather, and then pulling yourself up, like a pull-up in PE class for those of that.
So the lower body is the same thing, right? It's some sort of pushing away like a, a,
a squat or a split squat or a lunge or something like that.
And then some sort of, again, we'll call pull or hinge.
So a deadlift or a Romanian deadlift or a hamstring curl
or something where you're contracting and pulling the thing.
And you could split these into like a thousand different categories.
If you're really in that field, you're going to want to add a bunch of other ones.
But that's just like a rough conception.
So if you were going to do a single workout, you could choose four exercises.
And you could choose one of each.
One press, upper body press, one upper body pull, one low.
one lower body hinge, one lower body, press.
And that would be like a decently well-rounded exercise.
That's your exercise selection.
And if you're taking those through a full range of motion,
you're at a pretty good spot, as close as you can.
The next one is intensity.
So if you want to develop strength,
this comes back to one of my favorite scientists of all time,
who happens to be a nerve guy, actually.
And generally, I like to shit on nerves as much as I possibly can
because I'm a muscle guy.
But I have to give Heneman some credit here, right?
And I know you know who that is.
Anamen size principle.
Yeah, of course, right?
So this is a series of papers.
I think it was in nature.
At least some of them, yeah.
Yeah, in 1954, 56, or like something, you can fact-check me.
I'm sure you will.
But he basically outlined this idea that, okay,
there is a certain recruitment threshold needed for neurons to fire.
And we have muscle fibers in what we'll call fast-twitch muscle fibers and slow-titch
muscle fibers.
And in general, you're going to activate the slow-twitch ones first because they tend to be
associated with low threshold motor neurons. It's not exactly that way, but it's close enough,
right? Well, the only way that you activate some of these higher threshold neurons is to demand
the muscle to produce more force. And it's fairly specific to force, right? It's not something you can do
over an endurance thing, right, unless it gets really extreme and fatigue happens. So in general,
the only way to use these big chunks of your muscle, which are incredibly important for aging,
by the way. One of the major problems we have with aging developing, or development of aging-related
issues with muscle is the fact that we lose fast-switch fibers preferentially. And then we have major
problems as we go down the line because we've lost a big chunk of our strength and size. So you want to
make sure these fibers stay alive and intact. Okay. So if that being said, the only way to develop
strength is then to challenge the muscle to produce more total force. If you are fairly untrained
or new, I guess I should have stated this all at the beginning as well.
One more inception, then I'll stop.
When it comes to this level of detail of exercise prescription,
a fairly untrained person is going to respond basically the same
to every single thing you do.
In fact, we've done this in the lab many times.
We've done training studies doing things like 30 minutes of cycling
and seeing huge increases in muscle strength and size,
which is not a prescription for most people to increase size,
but people that are really untrained,
if you did pliometrics or strength training or endurance running, they all just get better at everything.
So that caveat kind of aside, if you want to be more intentional and more specific to the goal of strength,
you need to produce more force. Specificity matters, right? So we have size principle to help understand this.
And we have our laws of specificity, which say said principle, right? Specification to imposed demand.
So the adaptation you get or the result of your training is,
going to be a reflection of the demand that you imposed. So if you want to get stronger, you need to
impose a demand of strength, not repetitions. So this has to be, the load has to be very high.
In general, you're probably looking at above 85% of your winner at max. If you're moderately trained,
maybe 75% will work, lowly trained again. Everything works. But in general, we want to be pressing a load
that's very high. So because the intensity demand is so high, that is going to enforce you to do a low
repetition range. You can't do 12 reps at 95%. Then it wouldn't be 95% of your 1-R-R-M-Max. So by definition,
true strength training is really going to be in like five repetitions per set or less range.
That's where most of it's going to occur for specificity. So we've covered choice,
intensity, and repetitions, right? The total amount of sets that you use,
do is really kind of up to your personal fitness level, right? If you did as little as like three
sets for exercise, that's probably enough. Work sets. Totally. Yeah, totally work sets. Right. So get fully
warmed up and build up to that 85%. Don't just walk into the gym and throw 85% on and go, thank you.
That's an important distinction. So work your way up, do some, like a very classic warm up thing
would be like a set of 10 at 50%, a set of 8 at 60%,
a set of maybe 8 again at 70%,
and then maybe like a set of 5 at 75%.
So two or three or four sets,
kind of building intensity and lowering the rep range,
and then you would go after your two or three working sets.
Also, in terms of rest intervals,
now because we're trying to,
the primary driver of strength is intensity.
It's not the volume, right?
It's the intensity.
So in order to maintain that, we have to do a low repetition range.
But in addition, we also have to have a high rest interval.
Because if we start to, if we have any amount of fatigue incur,
and we have to then either reduce the reps or reduce the intensity,
we've lost the primary driver.
We've lost that main signal.
So the number we're going to throw out typically is like two to four minutes.
So imagine you did your setup bench press and you did five repetitions at 85%.
You probably want to rest two to four minutes before coming back to the bench.
That doesn't mean you have to sit there on your phone.
Like, in fact, please don't.
Everyone will thank you for not doing that, I promise.
You can engage other muscle groups.
This is what we call super setting.
So you're doing your bench press,
and while that two-minute clock is running for your chest to rest,
you can go over and do your deadlifts.
And so, you know, you can kind of move back and forth,
and this is how you can make strength training,
not seven-hour workout.
If you're a professional athlete,
you're going to take that time
because you want to maximize the outcome.
We've done this actually in our lab two.
Supersets will reduce the strength gains, but by a tiny amount.
And most of us don't care enough relative to it's going to triple the length of your training session.
It's not worth it.
So for the average person, I will tell them, yeah, superset.
For someone who's trying to break a world record in weightlifting or powerlifting, I don't super set.
Interesting.
Yeah, I think I've found that I don't recover particularly well from strength and hypertrophy training.
And the workout or the next day?
From workout to workout.
Unless I keep the total duration of those workouts,
I like to say no more than 60 minutes of work, of real work.
Yep, yep.
Maybe 75.
Past 75, I find that I just start to, I have to introduce additional rest days
or I just get weaker over time.
So I set a kind of a limit at 50 minutes and then I usually violate that limit
and end up doing 60 minutes.
So I'm excited to hear that one can superset exercises as long as they work different muscle groups, of course.
Yeah.
Right.
So I wouldn't want to do like bench press and overhead press supersetted because you can eat.
I think that goes without saying for most people, but just to point that out.
But that I could do some push pull, push pull without compromising total intensity that much.
And I certainly would be willing to give up a rep here or there or a few pounds here or there.
And may I ask whether or not in doing that one gets any even tiny bit or more of additional benefit in terms of cardiovascular work?
Because I imagine after all, even a one rep max, which I've never done, as I mentioned.
But let's say I get three reps on the overhead press and then I get four reps on a weighted pull-up and I'm going back and forth.
I'm no doubt going to be breathing harder than if I was sitting there texting away on my phone in between sets.
Yep, of course.
Yeah, and so in fact, in general, one of the things that I'll present in my class is a giant list of,
in fact, on the top is all these different actualized adaptations I started the conversation with.
And on the vertical column are as many of the physiological potential adaptations one would get.
So changes in endogenous pH, blood pressure, lymphatic changes, bone density, all these things, right?
And just have this giant list.
And then you can run a matrix and you can start to look at, okay, if I do speed training,
I'm going to see changes in the nervous system?
Well, like very much so, right?
That's the primary actual reason those things work.
Very little change in the muscle system.
It's almost exclusively explained by the central or peripheral nervous system, right?
On that same token, are you going to expect many cardiovascular adaptation from speed?
The answer is no, because although we didn't cover it, speed is very low intensity, very low rep range, very high rest.
Well, as you go to like strength and then you go to hypertrophy, you start seeing more and more increases in cardiovascular adaptations because you're doing.
exactly that, right? You're starting to reduce rest and you're starting to increase volume.
But you're going to lose things like bone mineral adaptations because the load starts to go down.
So you can look at this matrix and kind of understand if I'm a person who wants to kind of maximize
the adaptations I get across my entire physiology for the least amount of work,
you can choose these different adaptations to go after that are going to kind of land on these things,
right and exactly as you mentioned if you're going to take five minutes rest between each rep so let's say
the extreme you're going to do three sets of one repetition for strength at 95 percent you're going to take
probably five maybe seven minutes between each attempt like you better not expect many like changes in your
resting blood pressure that there's no cardiovascular strain there you're going to put it together in a
circuit where you're going to lose some potential strength adaptation but you're going to gain
something there so all these things are it's not about good or bad or right or wrong it's always about
what advantage do you want and what disadvantage do you want?
And I can cut like really end to the chase here on one of these things,
because we'll get to this eventually.
If you want to know the ones that are going to generally give you the most
physiological adaptations across the most categories,
you're almost always looking for a perch-be type of training,
and then this anaerobic conditioning piece that we'll get into,
that's going to hit the most systems at once.
That's great to know,
and we should definitely go a little bit deeper on those types of what the
modifiable variables,
for those categories because I think that I'm guessing the vast majority of people want to be a bit
stronger, maybe add a little bit of muscle or more, make sure their heart is healthy and
et cetera. This is wonderful and I think is clarifying certainly a lot for me. So for strength,
I guess training frequency. So what should determine training frequency? And I mean, I had the
great benefit of a long time ago when I was in high school actually. I paid for.
for a session over the phone with Mike Menser.
Oh, lovely.
The Mike Menser.
We have to be friends.
High intensity training.
At the time, I was pretty young,
and my mother kept saying,
like, why is this, like, grown man calling the house?
And we would talk all the time about training,
but he tried to convince me to train once every five to seven days,
very few sets, very high intensity.
And I must say, it worked incredibly well.
Sure.
It was, I think with my recovery quotient, which was not very good, I think it's improved over time, but it was not very good. It was remarkable. But of course, this was a time when I was, you know, I was full of the most animalism. I was 14. I was on my own version of anabolic. I was, right? I was, you know, really had a long arc of puberty. And you were untrained. And I was mostly untrained. I've been running cross country and skateboarding and playing soccer. So. And doing all the things that are like the antithesis of growing muscle. It was literally, and people will probably say impossible. It was something like four.
40 pounds of muscle inside of 12 months.
It was crazy.
I would believe that.
And so then of course that stopped working over time.
And then you start going down the odyssey of trying to find the thing that's going to work that well.
And you eventually realized that it was because you were untrained.
Right.
So training frequency is crucial.
Let's say that people are doing these whole body workouts as you've described them, not alternating upper body, lower body.
Because there's so many different splits that we probably doesn't make sense to go into
splits right now. But how often can and should one train a muscle? And how do you know if a muscle
is recovered locally? And how do you know if your nervous system is recovered system system
is recovered systemically? Okay, this is a bunch of really interesting questions. I'm not sure
exactly what route you want to go. So I'll start here. As I mentioned earlier,
soreness is not a good barometer of exercise quality because some types of training are going
to induce more soreness and some are going to induce less. That's important to this conversation
because when you ask about how do you know if a muscle is ready to train again,
one of the question is, what are you training for?
If you're training for hypertrophy, right, muscle-sized muscle growth,
we need to hedge towards recovery because what you're trying to do is cause a massive insult there,
allow then protein synthesis to occur, building of new tissue, which takes time,
48 to 72 hours, like kind of at a minimum, that process needs to occur.
If you're doing actually more strength, and this is a differentiation between hypertrophy,
and strength, then you didn't induce actually much damage.
In fact, you're generally not going to get very sore
from true strength training.
Very little, unless you get really heavy.
You did it a lot.
The primary driver of hypertrophy is not the same primary driver of strength.
We talked about that array.
That's intensity driven.
For hypertrophy, it's not intensity.
So because we have different mechanisms,
we have different outcomes,
even though they're closely aligned,
strength is not going to cause a lot of soreness.
therefore intensity is the driver, therefore frequency can be as high as you want. So you can train
every single day, the same exact muscle if speed or power or strength are the primary training
tools. Because you need stimulus there. Skill as well, right? Practice. You know that as much as anybody.
Developing a new motor pattern requires a lot of repetitions, right? You don't need a tremendous
amount of rest. That's not a damage thing, right? It's a repattering issue. So strength
training. In fact, if you look at, again, true strength professional athletes, they're going to
train the same muscles basically every day. Wow. They're going to squat every day. And is that
because the primary mode of adaptation is recruitment of these high threshold motor units? So it's
mainly neural. No. So everyone's going to say that. And this is where I get all feisty.
Well, I'm not saying that. That was actually, there was a question mark there. If we were online
putting comments, there would be a question mark. We would have fought. I would have blocked you. I was just
I think you already won.
Probably twice.
Okay.
The early adaptations to exercise, especially strength training,
are hedged towards the nervous system.
No question about it.
People always say central nervous system,
but it's probably more peripheral.
Whatever, semantics, probably, but pedantic.
It's nervous.
If you train today, tomorrow morning,
you're not going to wake up with a actually increase
in contractile proteins and muscle.
Your muscle might be a little bit bigger
due to some acute swelling,
but you could have an pretty acute
that persists change in the nervous system, we'll call it,
that allows you to be stronger, like, within a couple of days.
Sustained hypertrophy is probably more along the lines of four weeks
where we can see that, right?
We can actually see changes like in the ultrasound.
Now, you're making changes immediately.
That protein synthesis process is happening very fast,
and it's going to last,
it just takes us time to measure it
in terms of a noticeable change in your whole muscle's size.
So that being said, the first four weeks we typical say are primarily nervous system.
After that, now we're starting to see most of the changes coming from the muscle side of the
equation.
So with strength development, it's a combination of three areas.
In fact, all muscle contraction has these same three things.
It starts off with some signal, right, from somewhere in the body, whether it's all the way
up the top or at the level of the spine, depending on if this is a reaction or an actual
conscious control.
from there that some signal has to tell the muscle to contract okay so signal is one two it's muscular
contraction and there's a lot of variables inside the muscle tissue itself that determine its functionality
and so if we took an individual biopsy and took a muscle fiber from you and took one from me
and we took those muscles out and put them in a petri dish and i tied one end to a force transducer
the other end to a thing that pulls it and we soaked it in a bath of calcium and a bunch of other
stuff, even if they were the same size, your fibers might contract a lot faster than mine,
even relative to size, or not, or slower, or there's various properties. So the intrinsic
fibers themselves determine a lot of functionality. From there, muscle fibers don't cause movements.
Muscle fibers simply contract. They're all surrounded with connective tissue, and that's all surrounded
with a bunch of more connected tissue. That all surrounds into a muscle. That muscle is then
surrounded with more connected tissue. That all comes together.
into a giant tendon, that tendon attached to the bone.
It's pulling on those tendon
that actually move the bone that cause human movement.
So that's area three.
Area one, the nervous system area two,
the muscle contraction area three,
some sort of connective tissue thing.
Changes happen at all three of those levels.
And we're not even now talking,
even you entered the discussion of biomechanics
and you changed, say, the panacean angle of the muscle,
which is the angle at which the muscle fibers lay
relative to the bone.
Right, so this is basic mechanics.
Is it pulling perpendicular to the bone?
is it pulling horizontal to the bone or some sort of angle.
All of these things determine human performance.
So when you're talking about, again, that strength development,
you can see tremendous improvements in total force production
by manipulating all of those areas
and you have not touched changes in muscle size.
If you change muscle size in a true sustained fashion,
whether this is circoplasmic or contractile proteins,
you have given yourself more opportunity to produce more force.
It doesn't guarantee you produce more force.
Bodybuilders are not stronger than power lifters,
even though they have more muscle.
But bodybuilders are probably stronger than most people.
So there is a relationship between muscle size and strength.
It's not a one-to-one guaranteed ratio,
and that's generally because although the muscle has been aided,
they may have not changed the biomechanical considerations.
They may have not changed the connected tissue,
nor the nervous system stuff.
And so that's why we see this giant relationship
that our value is pretty high
between strength and hypertrophy,
but if you really want to get to the ends of it,
it's not. And that matters to your actual question
10 minutes ago, because again,
you can train strength daily on the same muscle,
but if you want to allow for that process
of contract on proteins to add and grow,
then you're going to have to allow some recovery
because if you go back into that muscle too soon,
you're going to blunt the response,
you're going to stop it, you're going to cut it off,
you have all kinds of problems going on in the cell that are going to just attenuate that
growth response so i gave you the answer for strength training the answer for hypertrophy is
probably less than three out of ten on level of so you can go again in general you're probably
looking at 72 hours is the optimal window so if you trained your your shoulders on monday
you probably would want to train them again on tuesday if hypertrophies the goal maybe wednesday
maybe Thursday's best.
So something like in every two to three day window is probably,
and we know a little bit more now about why that is.
The gene cascade, the signaling response happens,
well, the signaling happens instantaneously, right, within seconds.
The gene cascade is probably in the peaked in the four-hour window,
like depending on which gene you want to look at,
but it's just kind of a snapshot.
But the protein synthesis process is 24 to 48-hour thing.
And so it tends to kind of look like let that thing,
finish and let that signal go back to baseline and then hit it again and then hit it again.
And now as long as you're providing the nutrients, the recovery should happen and you should
be able to sustain the same work output in the training session. So the stimulus stays high and the
recovery's there and you can now continue to grow muscle. You mentioned 48 to 72 hours for
hypertrophy. What if for whatever reasons, the training split, lifestyle factors, etc.
somebody say, let's use your example, trains shoulders on Monday. Ideally, they would train them
again on Thursday in their particular instance, somewhere Wednesday or Thursday, but they don't.
They wait until Saturday or Sunday for whatever reason. Maybe it's more compatible with their
work, work and other exercise schedule, whatever the reason. Are they actually losing hypertrophy
that they gained or they've missed a window to induce further hypertrophy?
It's probably better to think about it, the latter.
it's not that you've lost,
it's just you've just kind of lost an opportunity
to make more progress.
I will save you a little bit
and kind of going back to your hit program.
This is the original high intensity training,
the menser thing, right?
Which is not...
The hit with one eye,
not the high intensity interval training,
but high intensity training.
Correct.
One set to absolute failure,
maybe two for each muscle group.
20-minute workouts.
Dividing your body into a three-way split
and then literally training like six times a month.
which most people think that is absolutely crazy.
There's no way that's going to work.
And I can tell you, if you are untrained, you grow like a weed.
If you train hard enough.
Even if you're trained, look at the people Mike trained.
He put a lot of bodybuilders on really high levels.
Now, they had the same similar help you had at that time frame.
To be very clear, I was not taking exogenous hand in a box.
But your endogenous was just as good.
I probably was.
I wasn't measuring my levels there, but I probably would.
I grew easy.
And in general, I tend to grow pretty easily from weight training.
But the, but, and I should say that to Mike's credit, and I think this is an important message,
that he was the one who really said, look, unless you're going to make a professional career out of it,
do not run the health hazards of exogenous hormones.
You know, it's certainly not at your age.
So he deterred me from that, which was great, because it never entered my mind.
It just was one of those things where Mike Menser said, don't do it.
And he had clearly done it, right?
And so he's speaking from an informed place.
It never entered my mind.
But also, what was really wild
as I was continuing to run across country.
And so there was a tradeoff there at some point.
A bit of an interference.
But when you're young, you can get,
many people can get away with what at this age
would surely place me into a state of overtraining,
even at low volume.
We'll see.
Well, I mean, like the whole field on interference effects
has changed quite a bit recently,
which we can come back to if you want.
But just to finish out the idea here with that last question,
if you want to take five days or six days in between each muscle group,
you can do that.
In fact, if you look at the research, it's going to show that frequency is not that important.
Well, it's not that it's unimportant, but it can handle changes.
As long as you get to the same total volume.
So you can do that, you just have to do a lot more work in that one workout.
if you care about the six-week, eight-week thing.
If you're like, I'm in this for the next 60 years,
it's probably okay, right?
But it can be there.
The challenge with splitting up your training sessions
for hypertrophy into smaller numbers,
like once or twice a week,
it's just difficult to get that number.
It's typical to get that volume done.
Volume-wise,
the more recent meta-analyses are going to say
that you're probably looking at around 10,
working sets per muscle group per week. Seems to be kind of the minimum threshold that you're
going to want to hit. So if you did three sets of 10 at your shoulders on Monday, three sets of 10
shoulders Wednesday and three on Friday, that's nine working sets. If you wanted to do three different
shoulder exercises on Monday and hit your nine sets, it's not really actually going to be that
much different. The problem is 10 is kind of the minimum. You probably want to look for more like 15 to 20
fact, well-trained folks, 20-25, that becomes very challenging in one workout. In fact,
defuncto, you're not going to be able to do it, right? And so that is where it's not the frequency
that looks like it kills you. It's just the fact you have got to get, because the total driver
of strength is intensity, but the total driver of hypertrophy is volume, assumed you're taking it
to fatigue, right, or muscular failure. So it's just tough to get enough done. If you can,
and if you want to set your schedule up that way, like you probably remember, if you do those
types of training sessions where you're just going to completely exhaust a muscle, it's going to be
sore for a while. You're probably not going to come back. And that's sort of the logic behind that was
let's take this thing to tremendous failure and give it six days to recover. It can work. It's just not
the best. I think is one way to think about it for most people. It's also hard to do those workouts
without a training partner. If you really want to do them correctly. And stimulants and headphones and
all kinds of other things. Yeah. Well, anyway, that yeah, stimulants are not.
I certainly don't recommend those.
It may be a cup of coffee or two if that's your thing.
But and maybe some of the safer supplements,
but certainly not sorts of stimulants
that the guys in the 70s and 80s were famous for taking.
Or still use.
You talked about repetition ranges broadly for strength training.
So five or less.
You said frequency could be as often as every day.
Rest two to four minutes,
maybe even longer if you're going for one repetition maximum.
For hypertrophy.
Sure.
what are the repetition ranges that are effective?
And what are the ones that are most effective
if one is trying to maximize some of the other variables?
Like people don't want to spend more than an hour to 75 minutes in the gym.
Because I think that while the rep ranges might be quite broad,
as you alluded to earlier,
there's the practical, there are the practical constraints.
Yeah.
So what repetition ranges or percent of one repetition maximum
should people consider when thinking about hyperchievous?
Right.
the quick answer there is anywhere between like five to 30 reps per set that's going to show
across the literature pretty much equal hypertrophy games and we could have a really interesting
discussion about why that is but I'm just remembering one thing from a second ago I want to
give a better answer for the frequency you can do every single week for strength or every single
day for strength if you want though like what's probably minimally viable two twice per week
per muscle. So hamstrings, strength twice per week. That's a good number to get most people
really strong. You can do every single day. You don't need to though. So I want to make sure that
like I wasn't saying you have to train a muscle 85% every single day to get strong. Two is a good
number. Three is great, but probably even two is really effective. Got it. This explains the high
frequency of training for strength athletes that's always mystified me. Yeah. And the very long
workouts make sense because very long they're going to even train twice a day. Like even though the squat in the
morning squat in the afternoon, every day.
With their eating and they're sleeping, they probably don't have time for anything else.
That's why they're pros.
So that's their job, right?
That's what they do.
So, yeah, your hypertrophy.
Strength training, programming is somewhat complicated, right?
Because of, it's not the danger, but you're going to have to pay one way or the other, right?
The risk is a little bit higher because the load's higher and you have to be a little bit more technically proficient.
When it comes to hypertrophy training, the way I like to explain it is it's kind of idiot proof.
the programming is idiot proof the work is hard though so here's your range anywhere between you know
five reps and 30 can you hit somewhere in there perfect it's all equally effective you can't screw that up
the only caveat for hypertrophy is you have to take it to muscular failure and you need enough rest
for the adaptation and protein synthesis to occur yep yeah right and if you recover faster you can maybe
do it more frequently and if you don't maybe less frequently by that logic should people perhaps
experiment and figure out what repetition range allows them to recover in concert with the
training frequency that they can do consistently. My recommendation is I think you should actually
set your, use the repetition range as a way to have some variation because most people don't
want to go in the gym and do three, six, ten. They're going to get very bored very quickly. And so I think
you should actually intentionally change the rep schemes for simple sake of having more fun. It is a very
different challenge. The mechanisms that are inducing hyperchemy are different,
but there's only a maximum amount of growth that one can get, right? And so you have, as best we think
it now, and some people actually will espouse that we know really clearly about the mechanisms
of muscle hypertrophy, we don't. It's still very much a guessing game, but the three most likely
drivers are one metabolic stress, two mechanical tension, and then three muscular damage.
You don't have to have all three. One is sufficient. You can have a little bit of
one or two, and you can kind of,
so you get it to play here.
We've already talked about the muscular damage.
Again, it's very clear,
more damage is not better.
But it is somewhat a decent proxy, right?
Like, again, a little bit of so soreness is good.
Just don't get so sore, it's compromising your total volume, right?
Mechanical tension is kind of like strength.
And this is why if you do even set up to five or eight,
and you're kind of close to that strength range,
you will gain a little bit of muscle.
It's not optimal muscle gain, but you're going to gain some
because everything in these, like physiology didn't cut off at four reps,
and then five reps is a different thing, right?
It's always a blend, so think of it as like a fading curve.
As you get closer to the end, it fades less effective.
As you get closer to the middle, it's more effective.
Anywhere between eight reps per set to 30, it's equally effective.
Past 30, it's going to blend out.
Past eight to five to four to three, it's going to blend, you know, lesser there.
So metabolic stress is one.
the damage is the other, sorry, mechanical tension is the one that's heavy,
muscle damage the other one.
The third one is metabolic stress.
And this is, I get a bit of an area of scientific contention, but something's there.
I know something's there.
We're just kind of fumbling to figure out what exactly it is.
And this is, metabolic stress is the burn, right?
It's there.
It's why blood flow restriction training probably works.
That's done very light.
So there's no mechanical tension.
There's very little damage, but somehow it induces,
a good amount of hypertrophy.
Very painful.
Oh, boy.
I tried this.
I have a friend, former special operator who was out on the East Coast and took me through a blood flow
restriction training protocol in a park.
And I don't think I actually cried.
You probably did.
But I might have cried out once or twice.
It was unbelievable, especially the lower body movements.
Now, it was a humid day.
I'll claim a little bit of jet lag.
But it was brutal.
It was really brutal.
Do it on the best day of your life and it's still brutal.
Okay.
Well, that makes me feel a little bit better.
It was intense.
And people should know that it is important to use the proper cuffs for these things.
I don't have any relationship to any of the companies that sell these cuffs.
But the reason is that you actually need to block particular avenues of blood flow.
You can't simply cinch off a muscle.
You can't turn to get a muscle and train.
You can actually kill yourself that way.
Yeah, you can get a blood clot.
Yeah.
And so if you're interested in blood flow restriction training,
I imagine you have some content about this or will at some point,
but also there are resources online that people can look up.
A question about hypertrophy train, I think many people are wondering about
train to failure or don't train to failure, assuming good form.
Yeah, okay, assuming good form, great.
The answer is both.
So you want to train to failure, but you don't need to go to extreme failure.
So you don't need to necessarily go to that like a partner has to lift the
barbell off my chest. But you have to get close. You have to drive either heavy, stress,
damage, right, or pump. And so a really easy practical way to think about this. I heard Mike
Israel who runs a company called Renaissance periodization years ago, outlined this at a NSA talk.
And it was beautiful. And I thought this is the most eloquent way to explain the context about
training for hyperetry. So I want you to look for three things in your workout. And let's say
that you want a particular muscle to grow.
Let's say you want your glutes to get larger.
Okay, when you're doing your glute exercises,
number one, are you feeling the glute contract?
Okay, it doesn't have to be there,
but that's a good sign if it is.
Okay, let's say I didn't really feel my glute contract.
I felt it more of my quads or my back.
Okay.
Did you feel a big pump afterwards?
No, I didn't really feel a pump there either word, or during.
Okay, great.
Number three, next day, did you feel a little bit of soreness there at all?
No, I didn't.
Well, that's a very good indication.
You didn't feel it during the workout.
You felt no sort of pump and it didn't get sore.
Don't expect much growth.
Didn't happen.
You distributed the work across a bunch of muscle groups.
Most likely other muscle groups were too involved, right?
Especially if you're like, no, but man, my back got really so.
Well, that's a really good indication of telling you what the hell was moving.
And so in terms of targets, if you were to put, again, a one to, you know, 10 scale,
how much should I feel it burning during?
Anything less than a three?
okay, it's probably not doing much, right?
But it doesn't, like, seven is not, a 10 is not better than seven.
You need to feel it, but it doesn't have to be like, oh, my gosh, I'm dying here.
Soreness, same barometer, right?
So if you can get like three, three, and three, you're probably in a pretty good spot.
Five, five, and five is maybe better, but you don't need to go much past that.
So I want you to feel the muscle group either working or if you're like, I didn't feel
it much, I didn't really get a pump, but the next day it got really sore,
then you're still, you know, on a good path.
Again, really sore as in like, ooh, a little tender, but next day it's okay.
Day after that, I could train, no problem.
That's really what you want to go after.
And in terms of understanding, is this likely to produce some growth or not?
Excellent, excellent, very clear parameters and recommendations I know are benefiting me and will benefit a lot of people.
If you'd be willing to throw out a few sort of sets and rep parameters that could act as broad guidelines for people who want to,
explore further.
I realize that with all these modifiable variables,
that there's no one size fits all for strength.
I love this 5 to 30 for hypertrophy.
That's a pre-biddle thing.
I don't think I've ever done a 30 rep set of anything.
But now that you've thrown that out there,
I see it as a bit of a challenge.
You want to know what's awesome about 30?
You're going to get an insane pump.
You're going to burn like crazy,
but you won't get super sore.
Because the mechanical tension is so low.
It's so light.
So you can get away with those things.
And you, it's hard because your mind
is going to wander. You're going to get it like rep 20. You're like, I'm done. And you're like,
no, there's a lot left here to get 30 where like a set of 10 is much easier. Like, you're just
like, okay, two more, two more. So a 30 is like, I got 16 more. It's awful. But you're not
just, the counting is work. It's terrible. Right. And people tend to just kind of like check out.
So 30 is possible, but a little bit extreme, extreme. But I would recommend all of them.
Like, it's a really fun play. You can do different in the same workout too, by the way.
Like you could do one set of 10 pushups and then take a little bit.
break and then do a set of 25. You can mix and match these things. There's no magic recipe that has to
happen for all those or do it different. So Mondays are my sets of 10 days, Wednesdays are my set of 20
days and Fridays are my set of 30 days. And you can have all kinds of fun there and it's hard to screw up.
Great. I love that phrase is always reassuring. So for strength, is there a sets and reps protocol
that is pretty surefire? So a way to just think about a really fast answer for
power, well, speed, power, and strength is what I just call the three to five concept. All right. So pick
three to five exercises. If you're feeling better that day, choose on the higher end. If you're feeling
less that day or you have a shorter time frame to train, go less. So this would be three sets,
or three exercises rather, or five exercises the most. So three to five exercises, do three to five
reps, three to five sets, take three to five minutes rest in between, and do it three to five times
a week. So that can be as little as three sets of three for three exercises, three times a week.
That's a 20-minute workout three times a week. It can be as high as five sets of five for five
exercises five days a week. So it's very broad and allows people to still stay within the domains of
strength and power while still being able to move and contour tour their lifestyle and soreness
and time and all those things. The only differentiator to pay attention to between power and strength,
is intensity.
So if you want strength,
this is now 85% plus of your max, right?
If you want power,
it needs to be a lot lighter
because you need to move more
towards the velocity
into the spectrum
because power is strength
multiplied by speed.
So while getting stronger,
by definition, can help power.
You probably want to spend more of your time
in the 40% to 70% range,
like plus or minus.
So that's it.
Both of them conceptually,
they'll work everything else.
The exercise, the reps,
the frequency, all that can be still in the three to five range,
just change the intensity depending on which outcome you want.
The nervous system obviously plays an important role
at the level of nerves controlling the contraction of muscle fibers.
But of course, we have these upper motor neurons,
which are the ones that reside in our brain
that control the lower motor neurons that control muscle.
And this takes us into the realm of where the mind is at
during a particular movement.
And to me, this is not an abstract thing.
I can imagine doing workouts that are mainly focused on strength or mainly focused on hypertrophy.
And in the case of strength, am I trying to move weights?
And when I'm trying to generate hypertrophy, am I trying to, quote, unquote, challenge muscles?
In other words, if I'm just trying to move a weight away from my body, you know, pushing a bench press or an overhead press,
I don't know that I want my mind thinking about the contraction of my medial delts.
I think I want my mind in getting the weight overhead with the best proper form, best, excuse me, and proper form.
And certainly with hypertrophy training, best in proper form is going to be the target as well.
But that simple, or I should say subtle mental shift changes the patterns of nerve fiber recruitment.
So can we say to get stronger focus on moving weights still with proper form and safely and to get hypertrophy,
focus on challenging muscles still with proper form and safely.
It's very fair.
Yeah, as a snapshot answer, it is a very fair thing to think about.
Intentionality matters for both.
In other words, if you look at some interesting science that's been done on power development
and speed development, the intent to move is actually more important than the actual
movement velocity.
So if you're doing, say, something for power or strength, and you're doing just a
to get the bar up. That will result in less improvements in strength than even if you're moving
at the exact same speed, but you're intending to move faster. And this is one of the reasons why
good coaching matters. So if you're coaching an athlete through a power workout especially,
and they're doing enough to just lift 50% of their winner at max, it's not going to generate
as much speed development as them trying to move that bar as fast as they can, even if the net result
is the same bar by velocity. Turns out nerves matter. That's it. I mean, I was about to say,
but as a neuroscientist, if I say amazing that nerves matter.
What's amazing to me is what, if I understand correctly,
what you're saying is that even if the bar is moving
at the same speed, same weight,
if my internal representation, my thoughts are,
I'm trying to move this as fast as possible
versus I'm just trying to get the bar away from me
and get the weight up, I'm going to get different outcomes.
Yep, this is quality of work, right?
This is, did you do enough to just check off the box,
or did you actually strive
for adaptation, right?
Similar concept actually works ripertrophy
in terms of there is a handful of very recent studies
that have looked at what we'll call the mind muscle connection.
And this is doing things like imagine a bicep curl.
And you're simply looking at and watching your biceps
and you're thinking about contracting it harder.
Even though you execute the same repetitions
at the same exact intensity,
initial indications are the mind-body connection
are going to result in more growth than not.
You just gave authorization for people to look at their muscles contracting in the gym.
Please do.
Yeah, of course, right?
But the selfie is still ruled out.
I'd rather you look at your muscles than your phone.
So I'm fine with it.
Those are initial.
We don't have a large depth of research to support that.
Maybe some stuff will come encounter it.
But it does, it matches what folks in that community have been saying for a very long time, right?
there's actually some stuff on simply flexing in between.
So if you've ever seen a bodybuilder,
they'll do their set of bicep curls,
and then they'll get out and they'll flex and they'll check.
And they're literally,
this is what Arnold did, right?
This is if you go back to pumping an iron.
Or college weight rooms, I should say.
For some reason, there's something about that age group.
Yeah.
There's a lot of checking of biceps in college weight rooms
for reasons that escape me.
If you ever interact with my wife,
like she will be the first to tell you,
I cannot walk past a mirror without like,
I'm checking something out.
That you can't or that she can.
I can't.
Not hurt, me.
I'm the one that cannot walk past.
All right, well, then I'll be careful not to disparage that.
It has nothing to do with the hypertrophy, but I'm just like, I'm a muscle guy.
So I'm always like thinking and tinkering or whatever.
But yeah, it is, I think it's very much worth your time to do a higher quality training
session, be more intentional, be present, than just executing the same exact workout.
I think that's globally very clear to be to your advantage.
So if you're thinking, like, I'm going to, like, I don't want to work out.
out today, I got all this going on or I'm tired or whatever, I'm just going to do the
workout anyways and get through it. Okay. If you can go, you know what, though, I'm going to
cut 15 minutes out of this thing. I'm going to get my head right. I'm going to go get 20 minutes
of quality work done. That's your best option by far.
You alluded to the fact that even just looking at a particular muscle might benefit in terms
of the number of fibers you can recruit or it's potential for hypertrophy.
I've heard before, and I certainly have experienced that muscles that, for whatever reason, genetics or sports that one played, et cetera,
muscles that we find that we can contract to the point of almost a slightly painful contraction seem to grow more readily than muscles that we can't recruit very easily.
And the reason I mentioned sports that we played earlier is, I mean, you just have to watch the Olympics to see that, you know,
swimmers obviously are very good at engaging their lats.
You look at the gymnasts, they seem to be very good at engaging everything.
And they go through a huge number of different dynamic movements.
That explains that.
So I find that if people say, oh, you know, I can't get stronger in this
or my whatever body part is weak in terms of it,
it's inability to engage hypertrophy.
Yeah, I see you're gone.
That oftentimes that can be because of an inability to engage those upper motor neurons
to deliberately isolate those muscles.
Are there ways that people can learn to engage particular muscle groups more effectively over time
for sake of hypertrophy or strength or for cases of trying to overcome injury potential or injury
because imbalances are bad across the board?
Yeah, this is actually very common and I think everyone has probably gone to this.
There's some part that you just can't get going.
For me, that was the lats.
That was the rhomboids.
So my back muscles.
For years, I couldn't activate my lats or my lats.
my rhombids. These are the muscle groups that connect your shoulder blades. So if you try to
squeeze your shoulder blades together, that set of muscles there, call your rhombids.
Your lats, of course, are more vertical and pull you kind of up and down. No matter how many
lap pull downs I did, bent rows, pull-ups, I could never see any development there, no increase
in strength. And it took me probably a decade to figure out how the hell to actually get these
things on. In fact, if you'd have asked me, even in my college years as a college football player,
hey, flexed your lats, like show me your lats,
you would have seen no movement there.
When I was doing a pull-up in that particular case,
the only way I could get the bar to move was by using my biceps.
So it's a synergiftic muscle.
It was supposed to be a secondary or tertiary muscle in that movement,
but for me it was primer because of my over-strength in my biceps
coupled with my lack of activation in the lats.
So you're compensating the same movement.
Actually, kind of an easy way to think about this is,
Imagine doing a bent row.
So imagine you're bent over kind of at a 45 degree
or a horizontal angle,
and you're going to pull a barbell to your belly button, right?
Now, you can actually do that exact same movement
with very little back muscle activation
by simply flexing your elbows more.
And so you think the barbell's going all the way down,
it's coming all the way up to touching my belly,
and you think you're doing a great back development exercise.
When, in fact, because of the way that you're executing the movement,
you're getting very little back development.
And this is a really good example
of why someone has to be a really good example of why someone
has done a specific exercise many, many, many times,
but yet failed to see development in a muscle group,
which goes back to earlier part of our conversation,
which is why exercises themselves do not determine the adaptation.
It's the execution that matters, right?
It's the technique, it's the rep range.
All of those are going to determine your actual result.
So if any time you're banging your head against the wall
and thinking like, why am I not getting movement here,
growth or strength or whatever,
it's almost one of those,
it's guaranteed to be one of those.
areas, right? You're probably not getting the muscle groups to activate. In that particular
example, just because we're here, try. Imagine doing that bent row. Instead of pulling the barbedal
to your belly, squeeze your shoulder blades together first as far as they can possibly go,
and then bring your elbows up without changing the angle of your elbow. So in other words,
without bringing your hand closer to your shoulder. So keep that same angle and come up as high as you
possibly can and then finish out the movement. That's going to guarantee a, a uterable,
first of the back muscles and a finishing with the biceps at the end, which is how that movement
is supposed to go. So how do you coach into that? Well, it can be a number of things. Whenever I'm
diagnosing movement quality, I look for a handful of things, but very first one is awareness.
You'd be surprised how many folks, when you just simply tell them that muscle group right there,
and maybe you give them a tactical prompt, so you touch it or you put something against it.
This is actually why, sorry I'm jumping over the place,
but this is why things like a belt work very well
for actually increasing abdominal strength.
So a misconception out there is if you wear like a belt
when you're lifting, then the belt kind of does all the work
for you and your abs get weaker.
That can happen, but the exact opposite can happen as well.
So if you take a belt, for example,
and you cinch it down really tight,
and then you just completely disregard your midsection,
you will see a loss of strength in your midsection
because now the belt is doing the work.
But if you put the belt on just a little bit,
kind of tight to where you get some sensory feedback
and you think about using that belt
as a way to activate the core musculature,
you will actually see a higher
if we look at like EMG activation.
The core muscles would be activated higher
to a greater extent than when the belt is off.
Because of proprioceptive feedback.
100%.
And for those that are wondering
what proprioceptive feedback is,
Probioseceptive feedback is that there are nerves that extend out to the muscles that control muscle contractions,
but then there are sensory inputs from the skin and muscle that go back into the nervous system and those work in concert.
And that feedback is proprioceptive.
I think it literally translates to knowledge of where one's limbs are and what's happening on those limbs.
I've seen, I don't have a training partner, but I've seen in gyms where someone will be training and someone will tap the muscle of the person.
who's doing the work in order to,
this is consensual tapping of other people's muscles,
not walking around,
touching people's muscles, please.
That, to provide that proprioceptive feedback
so that the person doing the exercises,
it becomes more aware of the muscle
that they're supposed to be training.
And it seems that that's probably an effective practice.
Yeah, I'll give you two examples.
I'll go to the back with that pulling movement,
but then I'll stay in the belt really quickly.
So a very easy example that you can do right now listening.
And I learned this from Brian McKenzie.
or mutual friend, right? So if you take your hands and open them up, like you make an L with both
your hands, and now take those and put them around your waist just above your hip bones.
Now, what I want you to do is press out as hard as you can on your hands with your core.
And you can feel a lot of core activation. Most people think core activation is the front of your
stomach, right? Your six-pack. What you need to do is create a cylinder around your back. So it's the
front, it's the side, and it's the back. So if you take your two fingers, point them,
Now put them just outside your belly button.
Can you move your fingers
by just moving your ab muscles?
90% of people can say do yes.
Same exact thing.
Now go to that same position
just above what's called your ASIS,
so your anterior superior ellioc spine,
right up that front of your hip bone,
right in the front.
Can you now move?
Great. 50% of people
are not going to get any movement there.
Really?
Take your thumb and go right above your PSIS.
My what?
PSIS.
It's posterior superior of the spine.
Right?
Now, can you move?
Most likely, no.
Sort of if I do a mini little back extension.
Don't.
Just with your core musculature.
Barely.
Yeah.
90% of people can't.
If you can't perform that contraction,
you can't stabilize your spine.
So only way to get stabilization
to your spine is then to go through hyper-extension.
And now that's a compression strategy
you're putting on your spine.
It's better than rounding your back,
like going forward.
but over extension is not great either.
So you want to be able to flex the muskature
in a cylindric fashion so you have control.
So if you go back to our very first things
and with your hands open
and you put them right here
and if you're like, I can't get activation,
if you pay attention to your thumb, right?
Now just move your thumb.
And now you see activation back there, right?
Boom.
Now if you can imagine turning that on just a little bit
and now notice how I can do this, by the way,
at the same time I'm talking.
If you have to go, we don't have control, right?
So you have to be able to separate breath from brace.
So now if I can put myself in a position,
and Kelly Starrett has always said 20%, give me 20% activation here,
and now I can squat, I can hinge, I can jump.
I don't need to be locked down to 100% scream
to be able to brace my spine.
That's going to be ineffective and wasteful.
I want to be here.
Well, the belt provides that proprioceptive feedback
where I can put it on 20%.
And it just is a reminder.
If I don't press against the belt,
the belt slides and falls down a little bit
because it's not on super tight.
If it's on so dang tight,
it's doing the work and I forget.
So we just want a little bit of feedback.
There.
Same thing with your upper back.
For having a difficult time activating
those rhomboids or those lats.
Someone can do a simple thing
where they take their finger,
put it right between your shoulder blades.
And you just tell them things like,
hey, squeeze my finger.
Squeeze my finger.
As you're doing your bent row or your pull down,
you can touch the lat.
you can do just visualization stuff.
So just imagine like a 3D rendering
of that muscle group
and you're watching that muscle group contract.
It's very powerful and very effective to do it.
So a touch, a visual,
all this stuff can help get people to activate.
Outside of simple awareness,
typically eccentric overload
is a very effective way
for activation of a difficult to target muscle.
So the lowering of the bar,
or the lowering of the weight.
the movement of the weight away from the body
is not necessarily always lowering
because that kind of depends on what most of the group you're doing, right?
I missbook, yeah.
Things like a pull-up.
Okay, so if I'm going to do a pull-up
and I have poor lat activation,
I can still get the pull-up muscle movement
executed by contraction of the biceps and things like that.
However, to make the movement simpler,
I'm going to go all the way to the top.
So imagine stepping on a box or something
going all the way to that top of that pull-up position
and starting from there,
and I want you to simply lower it,
under control.
And so you're just simply breaking the movement down
into smaller pieces that allow you to focus
on the execution more.
It's going to be great.
Ecentrics are great for strength development,
very good for hypertrophy,
and allow you to focus on control.
I'm willing to bet a huge percentage of you out there
who've like I've never had a sore lat,
even though I've done a lot of pull-ups and things like that.
If you do that eccentric only,
you'll probably wake up the next day going,
oh gosh, I feel it there.
And that's a sign even if you didn't feel it in the workout,
but it got a little sore the next day,
keep down that path.
And then eventually you'd be able to do a concentric,
maybe take a break,
maybe do an isometric where you just hold that position
and eventually work that into a progression
where you can do the concentric, eccentric,
and isometric portions and get activation.
So that may take you six weeks,
may take you six months,
but that's generally a pretty good strategy
for learning how to activate a muscle group.
Terrific suggestions.
Is it true that eccentric emphasized movement,
might require a little bit longer recovery
or they lead to more soreness than concentric movements?
Yeah, they typically can, but they're also higher force output.
So very good for strength development,
but they're going to lead on average to more soreness.
So more potential for intrast cellular disruption
that is going to be associated with pain.
There's not as much people will like to explain muscle
soreness as a result of micro trauma and micro tears in the muscle.
That can happen, but that's not the norm.
Most of the time, it is things like disruption of calcium
that's going to lead to excessive swelling, excessive pressure,
and that's going to be then translated as extreme pain.
So that's probably explaining more muscle soreness
than actually micro trauma.
Terrific.
I was going to get to breathing later,
but maybe just for now,
if we can do a brief little foray into breathing,
as it relates to weight training.
Is there a prescriptive for how to breathe,
during resistance training.
Here I'm thinking with weights,
not necessarily body weight-only movements,
although I suppose it could be,
that applies 75% of the time to 75% of people.
What I was taught,
and I'm hoping you're going to tell me this was wrong,
because then there might be more benefits awaiting me,
is that I should exhale on the effort
and inhale on the lesser effort portion of an exercise.
Is that true?
Is there a better way to breathe?
there is a better way to think about it.
So, number one, if you can breathe and brace,
then this conversation goes away.
So if you can maintain intramuscular,
intra-abdominal pressure while breathing,
then I don't really care when you breathe.
Very challenging to do at very heavy weights.
If we flagged this on two areas of a paradigm,
paradigm one over here,
you're going to do a set of 30.
And you're going to do front squats
where a barbell is sitting on your throat.
If you don't take a breath,
this is going to end one way and one way only,
you passing out.
Clearly has to be some breathing strategy.
The other end of the spectrum is,
let's say you're going to do a vertical jump.
You don't need any amount of breath there.
It's never going to happen, right?
The question is, what about in the middle?
So I'm doing some sort of strength training there.
Well, number one, make sure you're braced
and then you can get away with less need to worry about it.
In general,
a decent strategy is to maintain a breath hold
during the lowering or eccentric
or most dangerous part of the movement
and then you can exhale on the concentric portion.
So if the bench presses are example,
if you held in, braced,
lowered it under control,
and now started the concentric pushing away for it
and then you wanted to take an expiration
during the last half of the concentric portion,
that's an okay strategy.
If you're going to do a single rep,
you don't need to worry about it.
You can just avoid or omit breathing
entirely. You're going to be just fine. If you're doing more than that, especially three to four
to five to seven, eight, you're going to have to have some breathing strategy. A very common one is
probably every third breath. I'm going to do like, exhale and a third. Reset, rebreathe, something like
that. If you feel like you need to breathe after every one, that's okay, but it's going to get
wasteful because you have to take time in between reps of sitting there. If it's a squat, that's different
versus a deadlift, if you're resting at the bottom. So there is a little bit of game here. So in general,
is that 75, 75 kind of rule you thrown out, you threw out.
Breathe in, do the lowering, and exhale on the out.
If you have to, less reps, don't worry about it.
More reps, then you need to come up with some sort of breathing strategy.
How about breathing in between sets and maybe even after the workout?
Yeah.
This is something I think a lot of people overlook.
And because it is the case that recovery has to do both with the specific activation
and to muscles and the nervous system,
but also the attacks on the nervous system
can also take place between sets.
I mean, if you're really geared up between sets
and you go to adrenaline, you know,
as high in between sets or close to it
as you are during your sets,
you can imagine that the recovery would take longer,
or at least that you're not spending adrenaline
in the most efficient way, if there is such a thing.
Yeah, fair.
You're not going to see any athlete that I work with.
Just breathe in between.
Whether it's in between innings
or in between rounds,
every single one of them is going to go back, sit in the stool,
and they're going to immediately be into a breathing routine.
A very intentional one.
They're a little bit different for every athlete, depending on the sport.
Even PJ golfer, there's going to be a, we just hit our ball,
we're moving to the next one, we're going to go into a breathing strategy.
Every one of them.
It's a huge area of potential benefit and consequence if you're just ignoring it.
In general, we want to do any sort of calming breath.
We want to restore.
It depends on if the, it depends on we're combating,
are we combating low oxygen or high CO2?
So that strategy is going to be a little bit different.
But in general, that is a huge time opportunity to get better.
In fact, people can go back and listen to some of your earlier episodes
where you talked about, well, you have spoken about, I think, on this show,
when neuroplasticity works.
And if you're losing that opportunity, post-exercise,
you're leaving gains on the table.
if you will. So not only are you going to see everything the athletes that I work with mostly
have a breathing strategy in competition, we're not going to just finish a workout,
high five, drink water, and walk out of the gym. There will be a down-regulation strategy
that is heavily involved with some sort of light control as well as breath control. The individual
prescription on that, there's a ton of variation with what you can do. The easiest thing is do
something that calms you down. Most likely that's going to be moved towards as much nasal breathing
as you can possibly do.
And a really easy rule of thumb is a double exhale length relative to inhale.
So if you need to take a four second inhale, double that time and breathe out for eight seconds.
A box breathing is fine.
So equal inhale, equal hold, equal exhale, equal hold.
So four second inhale for second X hold, et cetera, et cetera.
A triangle is fine too.
There's a lot of ways you can get really complicated, like what Brian McKenzie will do and Rob,
those guys have, you can get all kinds of systems for inhale, Excel control, it can be optimized,
but some strategy of calm. We're going to almost always put you on your back or close,
and then we're going to cover light. We can do some, like we've done actually a number of
musical interventions as well, but you can as just as simple as sit down a locker room if you have to
and just breathe for five minutes. That alone is going to be productive.
That's great. If you're breathing in the locker room for five minutes, I suggest closing your eyes or you get some funny looks. And if you'll still get funny looks, but you won't see people looking at you. Yeah, exactly. I love this. And I started doing this because you and Brian McKenzie informed me about this. And it completely changed the rate of recovery for me. I realized that I was leaving workouts, both endurance workouts and strength hypertrophy workouts, feeling great, but looking at my phone, getting right into email and meetings, not concentrating on my breathing. And all I did was to introduce.
a, on your recommendation, a five-minute down-regulation.
So exhale-emphasized breathing, a bunch of different varieties,
physiological size, box breathing, exhale emphasized twice as long as the inhale component
for five minutes.
And I noticed two things.
One, I recovered more quickly, workout to workout, no question about it.
Yeah.
The numbers told me that.
And the other is that I used to have this dip in energy that would occur three or four
hours after a hard workout.
And I always thought that had to do with the fact that I generally eaten a meal at some point post workout.
Turns out it wasn't a meal at all.
It's that adrenaline ramp up during the workout.
I wasn't clamping that at the end.
And so I think eventually it just crashed.
And then three or four hours later, I'm having a hard time even reading what's on the screen of my computer thinking maybe it's the screen.
Maybe it was what I ate for lunch.
Turns out the down regulations allowed me to work through the afternoon with no issues whatsoever.
It's really been quite powerful.
And so I'm grateful to you for that.
And I think this is something that I think 98% of people are not doing.
And it's only five minutes.
You do you even have to do five.
Give me three.
If you really have to push it, give me three.
And you can even do this.
You can save time.
You can do this in the shower if you have to.
So you're done, you're finished.
Drink of water, whatever has to be.
And you're getting in a shower, getting ready.
Just give me three minutes in the shower.
It's not ideal, but as little as that, it can pay huge dividends.
you need some sort of internal signal that we're safe.
Like throttle down here, we're going to move on.
That has to happen.
I get going on and on here, but I think we're making the same point
kind of over again. It's a big deal and do it.
Yeah, and you're saving energy. I mean, the energy here is neural energy.
I think fighters do this. Good fighters learn to do this between rounds.
Sprinters learn to do this between events.
I think humans should learn how to do this between any, you know,
sort of interval type activity, including work, social engagement.
I mean, this is such a powerful tool.
Do this for one minute after every important, whether it's an individual, high, volatile
interaction, or if it's a, you just did a nice 45-minute sprint to work and you're deep
into it or whatever, fine.
Just give me one minute.
Set your alarm, just one minute, and that also will pay dividends.
I love it.
And as I said, it's made a outsize different, positive difference on.
my training, but also activities outside my training, which is, for me, I'm not a professional
athlete. I train for health because I enjoy it, but when a really hard workout starts to interfere with
the ability to do the other things in life, that's not a good situation. So this is really
terrific. There's a lot more in each of those categories of strength and hypertrophy, but you've
given us a tremendous amount of valuable information there. Maybe now would be a good time to shift
to endurance. And of the four types of endurance, and maybe you could remind us what those are,
what do you think are the two that most people are seeking or pursuing in terms of health
and aesthetics, right? I realize that we probably have athletes out there as well. But I think
when I think health and aesthetics, I think, okay, the ability to do sustained endurance, 30 plus
minutes of some ongoing activity, how does one maximize that work? What are the modifiable variables?
And then maybe you could tell us what the other major category is that people ought to have in their kit.
Okay. So starting off with exercise choice, one thing, as soon as we cross into the endurance world,
and this is true for all four of those categories, exercise choice needs to be very concerned with eccentric landing.
So you don't need to avoid it, but you need to recognize it. Relative or compared against those other strength and speed ones.
The volume is low on those ones.
you have some eccentric absorption, it's okay. But as we sort of talked about five minutes ago,
more eccentric means greater chance of muscle damage, so if you take something and magnify it across
30 minutes or even five minutes, but of maximum exertion, you have a recipe for blowing up.
You can imagine, I haven't run in forever. And I've just, I've listened to this Huberman lab
podcast and I'm, okay, I'm going to get into my zone two training, whatever, whatever. And I start
jogging. I'm going to do, I, you know, I remember when I was, I used to be able to do 25,
and you just do a 25-minute jog.
The amount of eccentric landing
that just occurred on every single step
because you're never, with running,
even slow running,
you never have two feet on the ground at the same time.
So it is a one-foot land, one-foot land,
your entire body mass plus gravity
onto one leg at a time,
repeated now hundreds of times.
That eccentric landing is going to cause tremendous soreness.
Your quads are going to go,
you're probably going to get shin splints,
which is what those are entirely caused by,
eccentric landing and when the tissue is not ready to tolerate that. If you're not landing correctly,
this is when knee pain happens, back pain, shoulder neck pain, because of movement compensation.
So anytime we start pressing to fatigue, let's be very concerned with there. So my initial
recommendation is start with activities exercise choice-wise that are mostly concentric based.
So think about a cycle. So when you're riding on a bike, you're pushing the pedal, but you're never
landing and absorbing it. So you could go out and do a 45-minute bike ride.
and you're not going to get that sore because there's not a lot of eccentric load.
Swimming, similar thing here, right?
There's some eccentrics when your hand hits the water, but fairly minimal.
It's mostly a push, push, push, push, no load.
Rowing, similar thing, mostly concentric.
Pushing a sled is fantastic.
Going uphill, running or even walking hard uphill.
All good because they're very minimal landing relative to like running downhill,
which would be a very, very bad idea.
to start. So if you're first jumping into these things, progress your volume for endurance very slowly
if it involves eccentric landing. A really bad strategy would be to jump in and do, say,
circuit training class that involves a bunch of box jumps, right? This is not a good way
to do your first foray into conditioning. You're going to get incredibly sore because you're jumping
in the landing. You're now looking at three to ten X.
body weight in terms of absorption with a single end, even if you're just jumping.
So be careful of that in any of those endurance areas of exercise choice.
So what to pick?
Pick the one that you are most technically proficient in because you're going to do it a lot.
It's going to be a lot of repetitions.
Whatever one you feel the most joy in, if that's rowing, great.
If that's pushing a sled, it doesn't really matter.
You can do this actually with weights.
This is our preferred way, by the way, with our athletes.
So we might do a 30-minute circuit where we do a few.
five-minute farmers carry with a pretty lightweight. So you're just going to carry some weights in your
hand and you're just going to walk up it down on the street for five minutes. You're going to set that down,
and then you're going to do, say, a three-minute plank. And then you're going to pick that up and
you're going to do body weight squats, like slowly and just tempoed. And you're going to do a handful of
different exercises so the athletes don't get super bored. Or a very simple one, if a 30-minute workout,
10 minutes on a treadmill, 10 minutes on a bike, 10 minutes on a row. But for those of you,
they're like, oh, my God, I can't do 30 straight minutes running. Cool, break it up. And
three or four different exercises that are all fairly safe.
So that's how I would do that long duration piece for exercise choice.
And then in terms of heart rate during that period, I mean, how much tension should we pay
to this?
The kind of very broad prescriptive I've thrown out on this podcast a few times based on my read
of the literature is for most people that are oriented toward health, including people that
are working on size and strength gains, hyperchapine strength, of course, that getting 150 to 180
minutes of so-called zone two cardio, you know, can just have a, just barely have a conversation,
but if one were to push any harder, you wouldn't be able to, that kind of thing. It's just a,
as a generic recommendation that almost everybody should follow in order to just keep their
cardiovascular system healthy. But I know there's a lot of nuance there. And some people would like to
be able to run continuously for an hour at speed, right? Obviously not sprinting. But what are
some of the finer, finer points on long distance endurance.
So how often should one do it?
Okay. Frequency, you could do it as daily.
Even when strength, doing strength and hypertrophy training.
Well, that I think is an important point for people to hear because a lot of people think
that they are going to greatly diminish their strength and hypertrophy gains, as it's often
called, by doing in zone two cardio.
Zone two, you have almost no ability to block your hypertrophy.
Zone two, truly, within that category, if it's really within that category, if you're talking
about conversational pace, there is very, in fact,
there's strong reason to think that is not gonna influence
hypertrophy for the overwhelming majority of people.
It might even help it by increasing blood flow
to the various.
Absolutely.
Does it matter, let's say someone's doing primarily
strength and hypertrophy.
Their primary goals are strength and hypertrophy
and then they're going to do,
they're gonna hit that 150 to 180 minutes
in zone two cardio per week, assuming they're breaking that up
into three or four sessions.
Does it matter if they do it in the same workout before
after, does that matter? I tend to do just by way of example for people. Certainly, I'm just one
example. I tend to do resistance training one day. Then I'll do zone two cardio the next day. I jog,
because that's the thing I prefer. Then I'll do strength hypertrophy train on the next day and then
jog for my zone two cardio and then I take one full day off a week. I've never actually done the
zone two cardio on the same day. But were I to do it on the same day, would it matter if I did it
before or after my strength hypertrophy training? Not really.
You're going to be just fine.
The interference effect is what this is called.
So this is all the way back to 1980 Bob Hickman's stuff, right?
And he was actually working in a lab with John Hulazi,
who's one of the fathers of exercise biochemistry.
And so the story goes that Hickman came in,
he was a strength training guy,
and Lazy, and almost all those initial exercise physiologists
were conditioning folks, right?
So it's almost always swimmers and runners.
And that's why a bulk of the exercise physiology,
historically is shaped in that direction.
It's one of those scientists were interested in.
So Hickman was there in the lab
and how much of this is myth or not.
Who really knows?
But so the story goes.
That this is sort of chipping back and forth.
And you know how from a PI to a postdoc
and kind of that razzing works a little bit.
And eventually he was like,
you got to start running with us.
And he was like, you got to start lifting with me
and kind of goes back and forth.
Well, you know who wins in that equation.
It's not the postdoc, right?
So the PI gets in and says,
okay, fine.
So he starts running with Alazi,
and then eventually starts to realize I'm getting weak.
I'm losing strength, and like, I just can't.
I think it was his bench press specifically was going down,
or maybe his squat.
I can't remember.
Who knows if it's even real?
But the point is.
So he's going along, and so eventually that starts to create
a little bit of animosity.
And it's like, actually, I don't think this is good for me,
and then blah, blah, blah.
And so they did what any good scientists would do
and said, well, let's find out, right?
And so he run a really famous experiment
where he took a group, three groups.
One group did a endurance piece,
the steady state cardio.
One group did a strength training piece.
And then the third group did both of those workouts combined.
Not like a reduction, so both volumes stacked on top of each other.
And the results are fairly predictable.
In terms of the endurance group only
have the greatest increases in V-O-2 max and endurance markers.
The strength training group had the greatest increases in muscle hypertrophy.
But where the interesting part was
and where this whole field started was the combined group.
So this is concurrent training.
is what it's generally called, so you're doing concurrent things.
And typically that means hypertrophy and strength stacked on top of some in steady state endurance.
In the same work.
Same workout.
Same two hour block.
Or same like week.
It doesn't really make it.
It can be kind of all these.
Well, the concurrent group saw the same improvements in V-O-2 max as the endurance group.
And he's like, well, okay.
So the strength training did not compromise the endurance adaptations.
However, they saw much lower increases in strength and hypertrophy.
And so the conclusion was the addition of endurance work
compromised muscle growth and strength development.
However, the addition of strength training to your endurance work
will not compromise your endurance gains.
Now, that second piece has been shown countless more times, right?
So if you're an endurance athlete, adding strength training
is almost always going to be massively beneficial.
very little chance of detriment.
This is why every endurance athlete
is going to have some sort of strength
and power component to their training.
The controversy, though, came in
the interference effect.
So how much endurance training
really blocks muscular development?
And for years, myself included,
was we preached hard.
You know, don't do these two things
at the same time.
My friend, my colleague, Kevin Murrick,
has a really nice review article,
Jimmy Bagley, those two guys put this thing out.
You can go read that
where they cover all these things
and they've got some nice figures in there.
But the general answer
here is, interference effect is sort of real, but it's probably greatly overblown. It matters.
So are you talking about a 20-minute jog at conversation pace? That's probably doing very little
with the assumption that are you doing an eccentric-based exercise like running? Well, then you're
going to have more of an interference effect than cycling. That makes a ton of sense if you think
about it, right? What's your total energy intake? If you're eating sufficient calories, you can still be
in an anabolic state.
If the addition of extra energy expenditure,
that's all it really is, mark the cardio,
put you in a negative energy state,
it's going to become very difficult to go through animalism.
So those things matter.
If you're talking about doing, like,
running a few laps around the track as a warm-up,
like that's not interference effect.
What we're really talking about
is a big volume performed consistently.
Now, after Hickman came out with this paper in 1980,
people followed it up in the 90s and 2000s,
with mechanism.
And we started to look and see,
and we started to see,
hey, there's this cell signaling pathway
that goes down called mTOR,
and that's what leads to muscle growth.
And then on the other side of that equation,
there's a thing called AMPK,
which is more associated with mitochondrial,
biogenesis, and endurance.
And there's this little molecule in between
at the time most people would point to TSC2.
Well, it turns out AMPK activation is fine.
If you activate mTOR,
that has no bearing on AMPT,
but if you activate the AMPK,
it's gonna activate TSC2,
which inhibited EMTOR.
And so it was like we had practical outcome,
i.e. Hickman, you're gonna get weaker.
Now we had mechanism.
So that story became very, very strong
that this interference effect,
and this is how science should work, right?
When you see mechanism match up
with practical human outcome, it's a strong thing.
That's what you want.
Yeah.
It was still wrong, though.
It just took more science, right?
And this is why we always have to give science a bit of time.
And, you, you,
have to be willing to follow, right? And again, even me in the field who has a practitioner background
and science, I felt very strongly. This is a big problem. It just didn't turn out to be the case.
Enough studies came out where I'm like, okay, it's probably not that big a deal. Unless the movement is
heavily eccentric based. The volume is very high. You're trying to maximize muscle growth and energy's
not controlled. If that's not all the case, interference effect is probably
Not something most people should worry about.
Especially when you compare that against the well-roundedness that you need for total physiological health.
Probably not a big deal.
Very reassuring for me to hear because I do enjoy lifting weights and I really enjoy running.
And I love running outside.
I believe I used to experience the interference effect when I used to do a very long run on Sundays.
I would just go out for, you know, two hours or something like that.
I don't know that I ate enough or who knows.
I always feel like I eat enough or more.
I love to eat.
But that long Sunday run always made it hard for me to make progressive gains in strength and hypertrophy in the gym.
Whereas when I cut that to 30 minutes, three or four times a week, I don't see any interference effect at all.
Probably very real.
And I haven't trained specifically for endurance in a very long time.
So I haven't experienced the non-interference effect, which, as you said before, most, if not all endurance,
athletes probably are or at least should be doing some sort of strength work just to keep the
undercarriage strong as I think. Yeah, there's a bunch of reasons. Yeah. So what are some protocols
that people could explore for continuous endurance training? I mean, I've thrown out this 150 to 180
minute zone two cardio, but that's really the kind of kindergarten of endurance. And there I'm probably
being generous. It's probably the nursery school of endurance that everyone should do. What sorts of other
protocols. I realize that can be very goal directed, but is it unreasonable, for instance,
for somebody to do four hours of continuous endurance training with intervals in there as well
to get it kind of all around heart health and the ability to go long distances?
Yeah, I'll answer this to is the very first one to tackle the long duration endurance is,
how I ever heard of it. You asked really about heart rate zones. To me, that's almost totally
irrelevant. It doesn't matter, right? If you're moving, you're moving, that's the functional
piece here. If you want to push it and go at a non-conversational pace, that has tremendous
health benefits. If you want to do it a little bit slower, fine. If you're at the pace where
you can have a conversation, to me, I don't even count that as exercise. That's not to,
it's not a pejorative, by the way. That is just general physical movement. It is extraordinarily
clear. You need a lot of that. You need a lot more of that than we get. You can do this in a
couple of efficient ways. Just taking your phone calls moving. If you've got a 30 minute call every day
or most days of the week and you can do that while moving, you've checked not that whole box,
but a pretty good chunk of it. And that could even be done inside. A hundred percent. Pacing back and
forth. I'm a big pacer. The, yeah, me too. Like, you probably saw me, like, I'm going to walk up
and down all over the place. Most of the time when I'm in my office working, like I'm shadowboxing,
like I'm doing air squats, not even intentionally. I'm just like. Do you have one of those treadmills under
the dust. I don't, but like every lab I ever came through, somebody did.
We did an episode on workspace optimization and the data on those treadmills are pretty
interesting. They definitely increase alertness, which for obvious reasons, even a little bit of
movement is going to generate a little bit of adrenaline. So pacing around, moving, taking
calls, moving, getting walks when you can. And then in terms of building endurance, let's say
somebody wants to, quote unquote, get into better shape. They already may or may not already have
some size and strength that they're happy with, and they just want to get in, they want to improve
their health. Yep. So when does that 150, 180 mid, this thing tick over into a different
protocol? Yeah. Okay. So I think the way that I can outline a weekly schedule, just as a
conceptual model here, that long duration stuff is not even counting, as I mentioned, right? It's just a,
this is what you need to do as a human moving forward. We haven't improved. If you're extremely unfit,
you may see some changes in cardiovascular health. But for the most part, this is just knocking out the
general physical practice, you need to be higher functioning. So whatever that time domain is,
I don't really care. It's not a huge concern of mine. What I think you need to hit are these nodes.
You need to do something once a week that gets you to a maximum heart rate. Now, I don't have to
literally mean max, but close. This means really sucking for air. Really. Like as high as you can
possibly get, you can wear a heart rate monitor if you want. But maximum heart rate,
the rough equation we say is 220 minus your age. So if you're 40 years old, your max, you're
maximum heart rate is probably about 180 beats per minute. Now, I can tell you flat out right now.
My max heart rate is close to 210, which means I'm 10 years old. So take that number with a
grain of salt. I have had a bunch of professional athletes who are in their 20s and their max heart rate's
175. And they are in way better shape than I am. So maximum heart rate is not a good proxy for
physical fitness. It's a rough number. An easy way to do it is if you have a heart rate monitor or anything
like that. Do the hardest workout you can possibly do. See what the highest number you get as,
as soon that's close. That's, if you want to just start at 220, minus your age, that's fine too.
Do something, though, where you're like, yep, this is death. Like, this is really, really challenging.
For how long?
However long that takes you. That can be a 30-second go on an aerodyne or aerosol bike.
That could be a, do one of those things where you kind of like sprint, run as hard as you can
during the straightaway on a track and then walk the corners.
Kind of an old classic back when you and I were kids interval training.
They don't do that anymore.
I guess.
I don't know.
I don't ever ever to talk about it.
In P.E class, we had to change.
And if you didn't bring running shoes, you had to do it barefoot.
Oh, I love it.
I love your teacher.
Yeah.
It wasn't a, our football, basketball, baseball teams weren't that good.
But anything like running cross country just because of where I grew up,
brutal, brutal coaches.
So, yeah, they'd make all kids do these runs.
Yeah.
So it can be in the 30.
probably seconds at a minimum, it's hard to get you to a true heart rate max in shorter than 30 seconds.
You can get the total suck in under 20 seconds, but getting to a true heart rate max is probably
going to take more than 30 seconds. So it doesn't really matter what you want to do. It can be,
again, a sprint uphill. It could be, well, you're talking, it could be burpees to death.
You know, like whatever, whatever you want to do. Although those have an eccentric component, right?
Yeah, they do. Yeah. No question about it. But if you did. Not to actual death, by the way.
Yeah. If you just did, I'm going to do as many burpees as I can for 90 seconds. It probably won't
take you much longer than that to get to close to max heart rate. Could be. So once a week,
get to max heart rate. Touch it. I love it. Touch it. It's not the best, but it'll, it'll work.
And what are the specific benefits that that provides? Okay, so earlier in our chat, we outlined
the rule of specific adaptation to impose demand. If you're never getting to that high,
of a pace. You're never, it would be like trying to get stronger, but only going to 60%. So every cardiovascular
adaptation that occurs with cardiovascular training is just simply going to get to the top or end by doing this.
So if you just start at the heart itself, stroke volume increase. So this is amount of blood that's
kicked out per contraction, cardiac output, resting heart rate. If you go to the endothelial
function, you're talking about nitric oxide release, endothelial health in general, capillary,
mitochondria all the way down.
You just walk through the whole system,
pulmonary exchange to the lungs.
All of those are going to benefit
by being challenged to their maximum.
You also teach you where your vomit reflex is.
Yeah, there you go.
Right.
Let's hope now.
Stress is what causes adaptation, right?
So if you push your, okay, here's the difference.
If you did 25 minutes of steady state,
you're not challenging the same thing
as what we just talked about.
The way that I explained this is
if you understand the point of physiological failure,
then you understand the place
of adaptation. That's it. So if you and I both go run on a, we did a both did a V02 Max test. So
classic VOTU Max test is going to take 8 to 12 minutes and it's going to look something like this.
We're going to get in a treadmill and we're going to run. And every minute I'm going to just
slightly increase that treadmill, either the speed or the grade. Most of the time it's the speed.
Right. So we get to a high grade, say 10% grade or something. And then we go five miles per hour,
5.2, 5.4. And we just go until you.
can't go any longer. Now let's say you and I did that and we had the same exact time frame.
And so we both went eight minutes. The time that you last is not the thing that we care about,
right? It's the volume of oxygen that you breathe out is what determines it. So let's say we move
the same time domain and we have the same VO2 max. Let's say they were both 50 milliliters per
kilogram per minute, which is like a okay number, but that's nothing to be extremely proud about.
Just because we have the same number does not mean we have the same point of physiological failure.
And this matters because it's going to answer the what do I do about it then question, right? So if you got off and I started asking you a series of questions and you're like, I basically said, why'd you quit? Why did you jump off the treadmill? Why'd you stop? And you were like, my chest, like I couldn't catch my breath. I thought my heart was going to explode. Okay, great. If you ask me and I said, my legs were on fire, like, I was breathing hard, but I couldn't take another step. This is a very rough indicator of different places of physiological.
disruption. Now, what I've seen a lot with my professional athletes, especially like fighters,
they're going to generally fail in their legs because they don't often do a lot of strength
training in their legs. They don't do a lot of leg work. They're fighting on their back, literally,
a lot or on top or on their knees. So their legs tend to give out before there. Someone who fails
in the cardiovascular system, like say you did a lot of leg training, typically like an endurance athlete,
who's, that's not going to be their issue. It's just going to be they're going to reach a heart rate
and ventilation threshold that's they can no longer handle.
If I put you on the exact same training protocols,
it's not going to be as effective because you're going to always fail at your legs
and they're going to always fail at their cardiovascular system.
I need to flip that, right?
You need to put you in a position to where you can reach a true heart rate or ventilation
challenge while your legs are still hanging in there or the opposite.
So the training protocol is based on that point of failure.
the adaptation is in the same thing.
So if you are failing because of your legs,
then you might see a greater increase in capitalization in your legs.
Relative to somebody else who's failing in their cardiovascular system,
they may see a greater change in something on that side of the equation.
So it matters how you're failing at all times.
What I love about this is that it sounds like it's like a thermometer
for where one is weak and needs work,
but also provides a stimulus to improve the very thing
that you need support.
So to just get real brass tax about it,
it would be once a week,
90 seconds near maximum heart rate.
Could I do more?
Could I do five or six of those 90 second bouts?
No question.
You can do, as long as you touch that max heart rate, I'm good, right?
Ideal world, probably four to eight.
In that single session.
Ideal.
Okay.
If that takes you 20 seconds or 90 seconds, it's fine.
if you want to do 30 on, 30 off,
you want to do 20 on, 40 off, 40 on, 20 off,
those numbers don't matter.
And is there an interference effect of this
on the other sorts of training that we've talked about?
It actually tends to be complementary.
There is, the evidence available
suggests that this high interval stuff
is more likely to be complementary
typeertry training,
probably because of lactate
and some other cool things,
which are very beneficial molecules
that people don't understand.
They think it's bad.
It's actually a hugely beneficial thing.
It can be,
interference can provide an interference if calories are not accounted for, if rest is not
accounted for and other things. But in general, it's probably okay. I wouldn't add it to your
equation if you don't need it for maximizing hypertrophy. But for the person who wants to just
get well-rounded physiology, yeah, I wouldn't hesitate to do these even in the same session or different
sessions. Terrific. So if that's done once a week and the 150 to 180 minutes or so of Zone 2
cardio is done, you know, in the rest of the week.
The person's doing their strength and hypertrophy training, we would hope.
What other sorts of endurance practices could one incorporate?
You mentioned muscular endurance, like the ability, would, like a wall sit or the ability
to do a plank.
Is that something, is that useful for anything?
Yes.
Except doing planks and wall sitting?
No, no, it's extraordinarily useful.
Let's hold on muscular endurance.
I want to finish one more thing on this side.
So if we're building this week of endurance.
once a week hit that number if you can do repeated bouts you know we talked four to eight that's fantastic
if you can't muscle the the if you can't manage the mental energy every week do it every other week
it's still very good right because i i get it like i'm a working person too and sometimes you're just
like i cannot like those workouts feel incredible afterwards but man they are daunting if you love this
stuff you could do it four times a week if you hate it though it's not realistic to think you're
going to be able to knock this out, you're going to end up doing 70, 80%, which is not going to
get you the benefit. So just don't do it. You really have to hit that ceiling. You've got to get up
there. Close. Have someone chased, I always say, you know, when doing this kind of work, in my mind,
I'm thinking that I'm basically being chased by somebody with a syringe full of poison.
And while there are other ways out of the situation, and for the benefit of what we're talking
about, what I'm referring to is to just run. Yeah. My motivation is typically, if
If you just get this done, we're done in a couple of minutes.
Just get it done.
Like, don't go here if you're not going to do it.
But when you show up, check in, and it's over really quickly.
Breathing down regulation afterwards?
100%.
You have to.
Right?
It's a huge key.
So if you absolutely can't do it, do it every other week.
That's twice month.
Give me twice a month.
It can be done on the road.
Can we done at 20 minutes?
Like do a really good thorough warmup.
Don't just jump into those, by the way, right away.
It's not going to be as beneficial.
Really nice, good sweat, broke.
a really good warm up and then give me four minutes of hard work and we're done right get out of there
if you want to use like a bath or hot thermal stress to kind of like aiding that warm up process
fine getting the sauna getting a hot bath to get really hot get up there warm up knock it out
the whole thing is 20 minutes plus five minutes breathing you got it i'm going to start doing this
it's so you got a bike right there yeah i've got all sort every every every room in this
studio that has a different piece of equipment it seems so i want that once a week realistically
every the week if I have to. I want that physical activity piece, call it whatever you want,
long duration thing. Ideally, you'll do as much of that through your nose only. You're not going to be
able to do to the interval stuff at nose only. Don't even try. But if you can go that whole 30 minute
time or 20 or 40 minutes, whatever it's going to be, that's actually a good way to regulate intensity.
So go as hard as you can while still being able to breathe through your nose only. If you have to
open up your mouth a little bit, fine, but try to stay there. What you'll see is very quickly,
you'll be able to increase your work output
while just breathing through your nose
which has a bunch of other
beyond benefits.
The other piece I want
is this middle ground
which is can you sustain hard work
for 8 to 12
maybe as little as 4 minutes?
I'll give you 4 to 12 minutes.
This doesn't have to be quite as high
as the first one.
You don't have to get to a heart and max
but can you get somewhere in the 80% range
and can you hold that for 4 minutes?
Maybe give me 2 minutes.
two minutes to rest and do that twice. Something like that. Ideal situation is what a runner would do is
what we'll call mile repeats because they're running four or five minute miles. Whatever time it
takes them to finish, they're going to rest that. So it's a one-to-one work to rest ratio. So a five-minute mile
rest five minutes and go again. That's probably pretty unrealistic for a lot of folks.
Well, the five-minute part is unrealistic for most folks. For me, it would be eight minutes, eight minutes.
Fine. Probably something like that.
In your particular case, just do the 800 meter.
So do 800 meters, do something that takes two to six minutes of work.
It is a lower intensity than the max stuff, but it's a much higher workload.
That is probably going to give you, you might even argue, the most cardiovascular benefit
because it is sustained work output.
And that's very critical.
The downside of kind of like that conversational pace, it's physical activity, it's movement,
it's blood flow, it's lymphatic drainage, it's not very very.
cardiovascularly challenging that. You're just not going to get an optimal health from just walking
actively. So two to six minutes of hard work. Of hard work with then an equivalent amount of rest in
between and then repeat how many times? Once if you have to. If it needs to be one rep, if it needs
to be a six minute thing and then downregulate breathe, twice if you can do that, six times, eight
times, like whatever you can really do. And you can just take that as long of the training session
as you want or short.
Exercise choice can be whatever you want.
So again, you can do sled pushes or it could be a kettlebell circuit or any combination of
things where you're just, you're working and you're not giving yourself a break.
You have got to be able to hold on at a very high waste product production level,
as well as a high demand for energy.
And then bring it down.
And breathing during this two to six minutes of hard output is,
mainly through the nose
or combination nose and mouth
or is that getting too technical?
Well, it's probably like I like it,
but you tell me if it's too technical.
You're going to try to maintain nasal only
as much as you can,
but you're going to lose it at some point.
You can go through
their Brian and Rob's gear system
and learn more,
and then you can kind of see what gear to be in
if you have to go nose in,
mouth out or something like that.
But I don't really care too much, honestly,
in that range.
I'm getting most of my nasal-only stuff
at night and training
and everything. So if you have to open up the throttle there to get the work done, that's okay.
Oh, then we'll actually go to answer your question, which was muscular endurance. Let's go back
to that piece. Muscular endurance is incredibly important for general maintenance of joint health.
In other words, you have got form follows function, right? It's a very classic sciencey,
physiology saying, meaning you've got a couple of different, there's a bunch, but to make it easy,
two different types of muscle fibers. Fast-twitch and slow-twitch. Fast-twitch fibers tend to be,
but they're not always bigger. They contract with a higher velocity. That's why they are called fast-twitch,
but they tend to be more glycolytic and thus fatigable. Slow-twitch are tend to be smaller,
while not always. They are more packed with mitochondria that we're generally better at burning fat
fat as fuel, but contract with lower velocity. Well, we have these two types so that we can regulate
function more. You have some muscle group.
groups that we're going to...
Sorry, let me go back up a quick second.
Each individual muscle in a human body
has a combination of some amount of fast
and some amount of slow.
That percentage of fast versus slow
differs from muscle to muscle.
So it also differs from person to person.
Easy example is your calf muscle.
There's three, but there's two primary muscles in your calf.
One's called the soleus, one's the gastroc.
The gastroc is the one
where if you take your toe and point it towards your face
and then flex, that's the one that pops out
you know on the medial side the inside the soleus is what we call it anti-gravity muscle and it is
generally about 80% to even 90% slow twitch and that's because it's supposed to be contracted lightly
all time it's supposed to be on permanently it's it's meant to keep you we call it anti-gravity
because it's meant to keep you erect up and moving your spinal erector is supposed to do this
various muscles for postural or are generally slow-titch muscles so we're supposed to be on all times
not produce fast, not produce force, but don't get tired.
The gas rock is the opposite.
It's not activated very often, but when it's activated, it's meant for extreme propulsion.
This gives us the ability to reach up and scratch our eyeball and also punch somebody.
We have to be able to regulate force output, which is going back to Heneman, right?
Controlling what we use when we don't use while also not wasting energy,
which is the downside of activating a big threshold motor neuron is it requires a ton of energy.
It's a more efficient mode of energy, but the total amount is really, really high.
So muscular endurance is going to help those slow twitch muscle fibers and slow twitch predominant muscles
maintain their working job.
So if you lose your muscular endurance ability in your spinal erectors or your calf, you're going to start slumping into bad positions.
You're going to be putting joints in a movement pattern that they're not going to be the most happy with.
So it's more about than being able to just maintain a two-minute wall squat.
It's about maintaining joint integrity and allowing that musculature to not fatigue when you ask it to do heavy and fast.
So what I mean by that is you've got a whole combination of muscles in your shoulder.
And we'll generally call these like the rotator cuff muscles.
Well, let's imagine those slow twitch, postural muscles get fatigued.
And they start to lose contractile tension.
and then you go to do something heavy or fast or in an emergency situation.
Those are already pre-fatigued.
You're going to rely more upon the fast-witch muscle fibers,
which are there less for postural integrity.
You're likely to get out of position.
And this is a whole recipe of like,
God, why has my shoulder just hurting?
Got my back.
That's very often a case of the slow-titch fibers
and the slow-chitch muscle groups
losing muscular endurance.
So you need to build that back up
so that they can control and hold the joint in the position
so the fast-witch virus has been contracted force.
I'm hoping that what I'm going to say next meets what you said accurately.
My experience is that getting injured, lifting weights,
or even doing housework or yard work almost always happens
when I'm not paying attention, fatigued.
That's kind of obvious.
But also getting in position to initiate a movement,
setting down a weight or lifting weights off the rack
or picking up dumbbells.
That's almost always when I seem to activate this lower back thing
that happens every six or eight months.
And what you're saying, if I understand correctly,
is that this muscular endurance from wall sits or planks
or things of that sort,
maybe you could give us a few other examples of these
can help us because they actually prepare the system
to do what we normally think of as the more intense work.
So it's really the, it sounds like it's really the architecture of the body
that includes nerves and muscles
and everything else, of course,
that lets the limbs and other kind of action end of the body do its best work.
Yeah, let it express its own power and force.
Yep.
We've actually landed on one of my final laws of strength conditioning,
which is similar to what I said earlier, right?
So I said, exercises do not determine adaptations.
Application determines adaptation.
So it sounds similar, but it's quite different.
There are no good or bad exercises.
There's only good or bad application.
here's a great example of that right so you do not get hurt deadlifting because deadlifts are dangerous
you only get hurt deadlifting because you either got in bad position you got in bad position because
you either got in bad position which is one of the things you just said or you ended up in bad
position you did too much volume you did too much intensity or you did too much complexity
Those last three things all hurt you because they result in the first one,
which is out of position.
Or another way to think about this is if it's not a visible change in position,
is stress got put into a part of the system that should not absorb that much stress.
So you did too much of it.
You did it too heavy.
You got fatigued, so you broke position.
You got too heavy, so you broke position.
You made the exercise too complex.
You put too many moving parts in it.
you put too many joints in it and you got out of position.
You did that too many times over time.
Now we've led for either an acute injury, bam, you know, back pops and you fall on the floor
or just like, man, this thing is hurting over time.
All these are the results of the same thing.
So you cannot ever blame the exercise for causing the problem.
It's always either the user or the coach.
You programmed way too much here and I can't handle that position or you yourself went into it too much.
So if you're getting these little tweaks and problems,
going on, you've made an error in one of those things. So simply back off. Reduce the complexity,
right? Give yourself more stability, less moving parts. Do less volume, do less intensity. In fact,
if you look at the people from the physical therapy world in terms of the pain literature,
it's very clear that just stopping a movement is very rarely going to work. What you want to do
is back off all the way down to just below that threshold of that's what aggravates it.
And you want to train right there. That's going to allow you to do two,
things. Number one, tissue tolerance, and then number two, desensitization. A lot of pain stuff,
and you can probably speak a lot about this, is, especially with things like low back pain,
is there's not necessarily often much damage there. It's a lot of hypersensitization of just
pain signal, pain signal. Omitting the movement entirely does not get that signal to go away.
You need to train just below that signal and desensitize it. So you want to make sure that the
muscular endurance allows you, you're just putting volume right below where you start to get
a tweak. And it is beautifully effective for that. I've experienced this right side lower back pain
for years, sometimes shooting down the hip. The two things that really helped were doing anterior
tib work. So, you know, hats off to knees over toes guy, Ben Patrick, who has, you know,
created a lot of popularity around tip work. But it turns out joints, full range of motion,
you're in a better spot. Yeah. Something about stabilizing the stuff from the knee down help my back
and then also some neck work.
And friends of mine are always teasing me
that my gym is filled with the most bizarre equipment.
You know, it doesn't look like any other gym.
A lot of it is just designed to keep me healthy and still training.
But I love this idea of getting right at the below the threshold of pain activation
and not simply going into complete non-action or just taking complete rest
because that actually can be detrimental.
I'd love to talk about a few items that support training of all kinds
and where there's a lot of confusion and indeed misconception and mystery and just get your take
on these. And I just want to acknowledge at the outset that for some of these, there's a lot of
science. For some of them, there's less science, but there certainly is a lot of experience in your camp.
And those categories are cold, heat, and hydration. Because obviously, whether or not you're a runner,
whether or not your strength training, if you're a human being, you need to hydrate. But in terms of
work output and physical work output, maybe even cognitive work output, maybe to tackle hydration
first. There is what I call and what I think is now come to be known as the Galpin equation,
which you really do deserve credit for because I think that people realize that there are a range
of solutions out there, but there is a really desperate need for straightforward solutions
that work for 75% of people 75% of the time. So hydration is key. Maybe you could
underscore just how
how key it is for us.
And then what is the Galpin equation?
As I call it and I think others are now referring to it.
Yeah.
Okay.
Benefits of hydration slash consequences of mishydration.
So whether that's dehydration or overload,
you,
physiology has hormetic curves.
Right?
Now typically we think about this in terms of toxicology.
So what this means is at some point
giving you a dose of something,
uh,
testosterone is very easy.
example. If you're clinically deficient or low in testosterone, and I give you a little bit,
and it brings you back to a normal range, you generally see an improvement in health and functionality.
Taking you, though, from normal to super high doesn't always necessarily provide additional benefit.
In fact, if you continue to go, it's going to provide detriment, right? So everything has this curve.
And then some things are hermetic stressors, which means like a small, short, fast insult is actually
beneficial because then you come back, bigger, faster, stronger. That's how adaptation work.
basic hormesis, okay?
Hydration's the same way.
So at the end of the curve here, if you are under hydrated, we all know, you could die, right?
You have to have things.
In fact, water is the only thing that is ubiquitous across biologies in terms of every living
thing has to have it.
There's no other vitamin mineral nutrient that is required among all living things with
the exception of water.
So that should give you a pretty good indication of it's importante, right?
Like, you've got to have this thing.
down here at the bottom
if you're dehydrated
and I give you more
its beneficial effects.
However, if you're up the top already
and I continue to give you more water past that,
now we run into actual problems
and we can get what's called hyponetremia
which is more common than people realize
nitremia being actually not referring to the water
but the sodium concentration being too low
and you've probably talked about that
at a length of why that's an issue.
If sodium potassium balances
outside a cell come off, you heart stops.
right muscle contraction ends and all these things um so you don't want to be over or under hydrated so
understanding this rough equation i sort of loosely calculated one day is helpful for that um i think
the most context is is talking about how much water to drink throughout the day and then how much
water to drink during exercise so the very easy answer is half your body weight and ounces per day
is a very loose guideline for total amount of fluid consumption so if you weigh 200 pounds aim for
100 ounces of water. It's like a very easy number. If you hit that, you're probably, I'd say,
90% of you are a good 90% of the time alone. If you then go to exercise, you need to then
account for that fluid loss with exercise. And in general, you want to consume 125% to 150%
of the amount of weight you lost in fluid. In other words, if you worked out and you were 200 pounds
naked, and you went and did your workout, and then you dried off, and you weighed yourself again,
you're 198 pounds. You lost two pounds of water. That's 32 ounces. You want to drink back about
125% of that. So instead of drinking 32 ounces, I want you to drink 40, 42, 45, like something
like this. Because one of the reasons why is unless you're drinking something that is isotonic,
meaning the same exact concentration in your blood, that you're in your fluid, you're just going to go
closer in that hyponetremia. You're going to get a bunch of barrel reflector reflexes and
you're going to actually think you have too much fluid and you're going to urinate it out.
What if I'm not weighing myself before and after workouts?
And is there a shorthand version of this that, you know,
after training for an hour, I should drink at least X number of ounces?
Assuming it's at kind of taller, you know, I'm not sweating super heavily.
Yeah.
In that particular case, you could probably go something like if everyone in the world
did, I don't know, 12 to 20 ounces. That's probably like pretty decent. And they're probably
doing that. Yeah. Yeah. And what about electrolytes, say consuming salt, potassium and magnesium?
But that thing only works though if you're coming in at optimal hydration. And this is the problem.
This is why you have to, you have to flag this starting with a good total daily amount of water.
Because if you're coming in and you're like, oh, I drank two or three glasses of water a day,
then you might need to drink 50 or 60 ounces post-workout because you're way behind.
So that like, oh, 12 ounces or so works if you're already generally very well hydrated.
And if people are drinking, you know, four to six glasses of water a day, but they're also
drinking a lot of caffeine in any form, then they're going to be excreting more water in most
cases, right? Because caffeine's a diuretic.
Okay, it kind of is, but it kind of isn't either. It's not the diuretic that we used to think
about it as. It is still fluid consumption. So it's only a diuretic if it caused you to excrete more
fluid than it actually was being in-tech. So,
if caffeine intake is in a normal range,
I don't have to worry about the diuretic effects.
If someone is drinking 12 cups of coffee a day,
or they're taking caffeine pills or something,
now the excretion is going to outkick the coverage.
So now we're going to have problems, right?
Because there's no fluid consumption with a caffeine pill.
So in general, things like tea consumption,
like I'm not super worried about those things.
You can count those towards your total fluid intake if you want.
So if you're like, I drink 60 ounces of water,
plus 20 ounces of coffee and then, you know, this, like, you're going to add that all up and you're
going to be totally okay. So natural, you also have problems with synthetic forms of caffeine
versus natural forms of caffeine. Natural forms are pretty okay. So coffee, tea, et cetera.
Yeah, all that's so. Pill form is where it gets tricky. Always, like always, right? So
general, just eat real food and things. You can be just fine. The last piece to consider is your
diet quality matters because the fluid content in your food can vary wildly. So something like
a bagel might be, you know, five to 10 percent water or something like a watermelon is 98%, 95
percent, something in a huge range, even meat is very high percentage of fluid intake. Like it's
really high. Even after you cook it, there's still a lot of fluid in there. So if you're eating
a whole food, mostly whole food,
your endogenous hydration is actually pretty high already
just from your fluid.
If you're eating a very highly processed,
dehydrated, oversalted diet,
you're way low on hydration just in your food.
So you have to factor all these things.
And in fact, one of the things that happens to us constantly
with folks that go from a highly processed,
low quality diet to a high quality one,
is they're just peeing nonstop.
And like, what the hell is going on?
I'm like, well, you actually have brought in
60 additional ounces of water in your diet,
relative to what you used to have, and you've gone from 10 grams of sodium there to four,
to two, sometimes one, sometimes it gets very low because you're not like salt. Are you salting
your food? No. Okay, well, we don't have sodium intake then. Like we're way down. So everything
that we're considering is based on that. So let's assume someone's eating a pretty well-balanced
diet. They're drinking 60 ounces of water and maybe some caffeine, coffee and tea,
things like that. We don't exactly know the optimal amount.
of sodium one should intake. It is very clear. High sodium concentrations are still associated
with a lot of negative health outcomes, especially in combination with poor physical activity,
in combination with low food quality and other comorbidities. That's a very bad thing.
You need to be very careful about those things. If everything else is okay, we're okay
playing with a little bit of higher salt. In fact, you're probably going to feel better. You're going to
feel generally pretty good. You just, it needs to be very clear. If you are overweight,
highly stressed, and you don't have a lot of these things ticked off,
and you have known core morbidities,
you really need to pay attention to salt intake.
It can be very nasty.
So that being said, what we're generally going to look at folks
is, are you at least, can we categorize you as a low-sodium or high-soidium sweater?
If so, there's a whole list of electrolytes you can look
that are going to have something like 200 to 400 milligrams per serving.
There's a whole list of these things.
If you're a low-odium sweater, I'm probably going to send you out.
after one of those. If you're a high sodium sweater,
there's a lot of electrolyte supplements
that are closer to six or 800,
even a whole gram per single serving size.
So you wanna play with that.
How do you know if you're a low sodium
or high sodium sweater?
We actually have an episode on salt.
We put out that, or is coming out soon,
if hasn't come out already, which is, you know,
when you look at the hazard ratios for salt intake,
basically your probability of really bad things happen to you
goes way up as you get towards, you know,
lot of sodium intake, you know, 10, 12 grams per day. And this is translated teaspoons
of salt, et cetera. But also very low sodium intake is a problem. No question about it. It's a,
it's not a perfect U-shape. It's kind of a J-shaped curve or a kind of hockey stick shape,
more or less. But how would I know if I'm a low sodium or a high sodium sweat?
Yeah. So you can get so. Would I just kind of lick my sweat or have someone else to do?
You can. Yeah. Find a super friend who will lick your sweat for you. That's same with how.
No willing volunteers that I'm aware of. But would I be able to
tell? Yeah. You can get sweat testing done. Actually, you have a number of options. The kind of
of the original one that most of us use in the background for many years was called leveling.
They'll send you out a little patch. You can wear that, send it in the lab, and they'll measure it
directly in the lab and send it back. It's 150 bucks or...
Did they bin you mean to low, medium, and high sodium? They're going to do that, but they're going to
give you very, they're going to tell you exactly the milligrams. And they're going to actually
tell you, like, what products and stuff that they're exactly matched. Do you do you?
this with professional athletes.
We have many times.
Yeah.
Interesting.
You can do a more consumer-grade version.
Gatorade has a patch.
For 25 bucks, you can get two of them.
You can put that patch on your left forearm and download the Gatorade app and you can do a
workout, measure it right there and click it over.
And they'll tell you exactly, not only higher low, but again, they'll tell you the
milligrams of sodium that are in your sweat.
And then you can figure out, again, kind of high, medium or low.
Interesting.
I do much better on a slightly higher sodium intake.
Most do.
But in my carbohydrate, I do eat carbohydrates on one of those that is pretty moderate,
but I try and eat clean food.
So I notice, and I tend to be slightly low blood pressure.
So again, to reiterate the warning there that if somebody is prehypertension or has hypertension
or obese, you really do need to be careful with your sodium intake.
But many people seem to find that they feel better when they increase their sodium intake,
and they're still in that healthy portion of the hazard ratio curve.
Most of the athletes, I would say in general, we're going to go higher in salt.
When they come, we're going to run their stuff, and we're going to add salt.
Almost always.
Very few times have I gone, ah, we need to cut this back.
One of the exceptions are the ones that come in that eat like 14-year-olds.
And I'm like, okay, you're at 15 milligrams, or you're 15 grams a day because you're eating nothing but...
Garbage.
So we're like, we're going to come down.
You're going to feel way better and all this bloating and everything else that's going to happen, go down.
You can do that.
There are actually more...
There are biosensors that are coming out that are not available yet, but they're coming very soon in this space.
They're going to be able to give you real time.
metrics on salt. So you can pay attention to those. I haven't seen one and used one personally,
so I don't want to espouse about how good or bad it is, but I know that those are coming
from a handful of companies. An easy way to do is just look at wear a hat or wear some sort of
headband or something and do your workout. Take it off. If you see a just huge white band,
or if it's completely clear, and that's going to tell you, big white band, you're probably a high
self sweater. Completely clear, very little coming out. That's great. And I can see the post on
Instagram now, people showing their salt band from from sweating. I mean, obviously salt is so essential
for so many physiological functions. You don't want too high or too low, but if you're losing more,
it makes sense you would need to take in more. So half of my body weight in ounces as a just
foundation of a fluid intake. Coffee and tea could be included in that, but that should probably
mostly water or things similar to it.
And then during exercise,
how do I want to think about this again?
Let's say I'm a high salt output,
then I'd want to drink maybe 40 ounces of water with or more.
Yeah, okay, I'll do this easier.
Let's talk about pre and mid and post, right?
So what to drink pre.
If you come in having hit these rules, you're okay.
And pre-workout can be as little as like five or six ounces.
basically a couple of sips of water. Fine. If you come in poorly hydrated, then you maybe need to go
more like 12, but here's the deal. If you start off a session in a bad spot, you're not going to
catch back up. Like you're in trouble. Let's say you come in, you follow a direction. 500 milligrams
salt before, 500 milligrams after. A very easy rule. Pick whatever source you want. That's a couple
of sprinkles of table salt. If you want Himalayan, that's fine. You don't have to. Himalans actually
a fairly low sodium salt, so it's not the best for this purposes.
If you're a higher salt or sweater, a little bit more,
if you want to go choose an electrolyte of which there are infinite,
you can look on the packet, and it'll tell you,
you know, 250 milligrams per searing or 400 or 600 or whatever happens to be,
but around 500 pre-500 posts is a very general rule.
And then during is, thanks to you,
my famous Galpin equation now that is all over the world.
All I did is I took the literature and I said,
okay, in general, the research shows pretty clearly two milligrams per kilogram body weight
every 15 minutes seems to put you in a pretty good spot. Most people don't think about kilograms
or millimeters. So can I just run that over? And then it turns out it's about your body weight
divided by 30 in ounces. Like that's all you have to. Body weight and pounds divided by 30.
Yeah, exactly, right? So you weigh 200 pounds divided by 30 and that's the number of ounces.
You're going to want to go every 15 or 20 minutes or so. So I'm getting that amount every 15 to
20 minutes throughout the training.
And now in the weight room, that's pretty easy to do
because there are rest intervals,
but people will need to do this while running or cycling,
and that can cause a little bit of gastric distress
if you're not used to it.
Is that right? You can learn to run with some water in your belly.
100%.
The gut is very trainable in a lot of directions,
but in terms of fluid as well as carbohydrate,
which is another thing that is going to get people,
but that's, yeah, very trainable.
It'll be uncomfortable initially, but you'll quickly get into it.
The better solution for those folks, just come in hydrated.
And you might not even need any water.
You could probably perform just fine.
So the ones that don't have as much of an opportunity, you really have to emphasize walking in.
We have this problem with like professional golfers.
They have plenty of time to drink water, but they're so focused on the shot and there's a lot of variables coming up.
Once they hit their shot and they're moving on in the next one, they're thinking about, I mean,
they're going over a scorecard of 100.
185 yards away. Can I go 184 and a half yards? Can I go 186 yard? What's the slope of that?
What's the wind up here? What's the wind up there? Like, there's just thinking and they just forget.
Even though they have four and a half hours. So we have to make sure that they immediately get off the
course. We go right into recovery as hard as we possibly can. They wake up the next morning.
They're in a good spot. We crush recovery. And now's like, hey, if you can remember to drink this,
great. If not, we're still fine. If it's not a big deal and you have time like in a
a lifter because I deal with that problem with fighters too. Like I we can only drink so much in the
middle of a fight a couple of sips over there but we we can't go mix them two millimeter a minute of it
it's like can you get a couple of sips in yet oh shit forgot like it's not going to happen so we have
to take more of an emphasis before and after so start your recovery process immediately and then come in
the next day that's your window and then whatever you can get in during the workout that's fine too
if you're a higher salt sweater instead of doing 500 500 maybe go 750 750 if you have a long
about of exercise, especially if it's hot or humid,
then you might want to consider some salt in the workout as well.
And 300 milligrams during the workout, totally fine.
It's enough.
If it is a really long workout and it's really hot
and you're going to lose pounds during it,
you need a specific strategy.
If you're going to lose less than a pound,
you don't need to worry about it.
It's not going to be enough of a detriment for you to really care.
So that's kind of a rough rule.
Now, if you're 200 plus pounds,
maybe that number moves from one pound to two pounds.
But really the number we're looking at is what 1% of your body weight.
If you're losing more than 1% of your body weight,
we need to start caring.
If it's less than 1%, it's not going to really pay that much of a difference.
Okay, so for myself, because I don't get super technical,
I don't wear any devices besides a wrist watch.
It's a nice watch.
Thanks.
Yeah, I do very attached to this watch, or it's attached to me, I suppose.
My body weight in pounds divided by two,
that's what I'm going to try and get across the entire day as a kind of baseline.
And then my body weight in pounds divided by 30 during the workout every 15 or 20 minutes,
that I'm going to try and consume that amount.
And then I definitely do better when I increase the amount of salt that I'm taking in anymore from 500 to 500 milligrams to a gram of salt several times a day, actually.
But I'm not eating that often, which leads me to my other question, which is I prefer to train fast.
or semi-fasted, meaning first thing in the morning or within an hour or two of waking,
obviously I've been fasting while I'm asleep, or having not eaten anything for three or four
hours before, I just feel lighter and more energetic. If that works for me, is that okay?
Or should I try, is it better to eat something before one trains?
Personal preference. Easy, easy answer there. It depends on, of course, how hard you trained,
what the training was like, what sport you're involved with, how many telecalis, etc.
But in general, personal preference for the average person.
That probably handles 90% of the questions about that.
Cold.
Cold showers, ice baths, and cold immersion up to the neck.
I always preface this by saying there are not a lot of studies.
There are some, but not a lot of controlled studies looking at cold showers because it's
harder to control the variables of where people stand.
And so I would say if you have access to cold immersion of some sort, ice bath or cold immersion, great.
But if you don't, cold showers will be the next best thing.
The lore goes that if you do an ice bath or cold water immersion after strength or hypertrophy training,
that you are short-circuiting some of that.
The lore also goes that cold showers might be okay.
And my interpretation of those data and that discussion is that all that is probably true.
but I have a hard time imagining that the effects are so robust that it can completely prevent
strength gains in hypertrophy such that my stance for myself is trying to do the cold exposure
training away from the strength in hypertrophy training. But if you can't do it any other time,
right afterward probably isn't going to throw my whole system out of whack and prevent the
improvements. Am I deluding myself?
A couple of caveats here. Number one.
And obviously I have a personal vested interest in cold.
I've been around this stuff for a long time.
Being involved and being an advisor for XPT and being in this space a long time, I'm a big believer in cold, especially cold water.
Deliberate cold exposure.
100%, right?
So that being said, I do think getting into an ice bath immediately after a hypertrophy session is getting pretty close to you just shouldn't have done the session.
it is detrimental.
Good to know.
I wouldn't do it.
I guess it's the most blunt way to put it.
If you're like, hey,
I'm not super concerned with growing muscle
and I want these other things
that come with cold water aversion,
fine. It's not zero. It's not zero.
It's not taking you backwards.
How much does it cut you down?
I don't know. We don't know that that would be a difficult
number to come up with.
Is it 1% reduction? No, it's more than that.
Is it 100? Not even close.
I don't know where it lands, though.
It's enough, though, for me to go, in general,
best practices, don't get in the ice immediately after a workout.
How long should I wait?
Well, in theory, the best answer we could give you would be four hours
because of what we talked about earlier today of going,
okay, immediately you've got this signaling cascade that takes seconds.
You've got gene expression that's happening in this rough four-hour window.
After the genes have gone off and now you're just going through the protein synthesis process,
the signal's already there and it's gone back down to baseline.
So then in reintroducing or introducing cold here,
is not going to disrupt that signal.
That's a very non-scientifically founded
because we don't know at this point at all.
What is very clear, though,
is if you get off your workout,
go right near the ice,
it's probably 10% attenuation of growth.
I don't know, maybe more depends on the person.
Some people, if you look at the individual data,
it's pretty bad.
It's enough to where it's like that's a really big deal.
The benefits of the ice,
I don't think now outweigh the benefits of the hypertrophy training.
What about cold showers?
I don't think cold showers are going to do much.
If you've been in both, you know that this is like we're not playing the same game here.
An ice bath or true cold water immersion up to the neck with limbs in
if for one to five minutes is a completely different stimulus than in the cold shower.
Especially also compared to a similar like cryo.
It's not even the same thing here.
So in general, I would say don't do those.
Cold shower, I don't really care.
Can you work it out so you don't do them the same time?
That would be my hope, right?
I would actually prefer you do the cold before
if you really had to do it.
Certainly we'll wake you up.
Get that adrenaline burst.
No, we've played with that actually years ago
doing that.
There's actually some fun stuff you can do
with the endurance piece with cold stuff,
but it's totally not feasible for most people
because you get out of,
you're getting water everywhere.
They're going to jump on your bike and just get shit
and it's just a giant mess.
It's fun.
But yeah, I would say walk away from it.
If you can, that's actually,
it's where I stand based on the data.
Based on my intuition
and experience, I don't think it's a good thing to do.
Now, having said that,
that's mostly concerned with maximizing hypertrophy.
Strength is not as clear.
There are some data to show
what actual block strength adaptations,
but because of what we talked about earlier,
the mechanisms and the drivers are different,
and so I don't think it's as big a concern
for strength development,
though I would still generally say
if you can get away with staying out of the ice
immediately after the workout
and you can at least wait a few hours,
that's the better approach.
Less concerned with strength,
more concerned with hypertrophy.
in terms of interference effect. If you can do it on off days or before or any other time,
that's the place to land. That's generally when I tried to do it. I was just kind of throwing out
an extreme case because I get asked that question a lot. What about the use of ice bath or cold water
immersion or cold shower after endurance training? Okay. So a couple of interesting things here.
You mentioned we don't have a tremendous amount of data on cold water immersion overall.
So a lot of this is moving.
there have been some papers to show that cold water immersion can actually enhance mitochondrial biogenesis
and actually even for endurance stuff it's been shown to cause improvement in endurance adaptations
relative to not it's not enough for me to be truly confident in that statement yet i would like to see
that repeated not not that i have a problem with the paper the methodology that they use in that particular
study but it's just like this is a weird thing so i want to see this repeated more often so i have less
concern with doing it immediately post endurance because you could even argue that there may be some
benefit. I don't think you need to go out of your way to try to make sure you get an ice immediately
afterwards and thinking you're going to get some massive adaptation. We use ice a decent amount
when I can get athletes to do it. But this context is different. Number one, when we're in camp
and we've got a world title fight coming up or something else, we've just pitched in it at a major
baseball game. I am not concerned about hypertrophy. I'm not even concerned of strength development. I
now pushing towards recovery. There's a paradigm that I think is important with all of these things
to understand, which is, are you pushing for optimization or adaptation? When you're pushing for
adaptation, you don't want to block the signal for adaptation. This means less recovery. You're not
going to feel as good, and you probably should be hedging towards stress. When you're pushing for
optimization, it's the opposite. So if I'm in season and I had a pitcher just throw 125 pitches,
I'm not trying to cause adaptation. I'm trying to recover as quickly as possible because
four days from now, we've got to do this again. And I got to do this across 162 games.
You're going to play six days, five days in a PGA golf tournament, and you're going to have to do it again every week for a bunch of weeks in a row.
I need recovery as fast as I possibly can. So if I'm blunting adaptation, fine. I'm not actually trying to do so. I'm trying to optimize.
If you spend all of your time in one of those two areas, you're going to have problems. So you need to be judicious about thinking, is this a point in my life or a training cycle that I want to cause adaptations, or am
am I trying to optimize? You spend too much time and one of the other ones, again, you're
going to have problems. So that's in generally how I will treat the ice for all those adaptations.
What about heat? Yeah. And I'll frame this question differently because I'm sure there are
a number of ways in which heat can short circuit all sorts of things. I mean, heat in excess can
kill you. It can shut down fertility. It can in excess, right? It can do all sorts of things. But it
can also increase growth hormone, increase basal dilation, improve one's ability to sweat,
which can be very beneficial in a number of contexts.
Yeah.
For the typical, for 75% of people, 75% of the time, when do you think heat is most useful?
And here I'm referring to dry sauna or wet sauna.
I'm not specifically talking about infrared sauna because the data there are a little unclear
to me.
And I don't even know that my sense with infrared saunas is they don't go hot enough for my
particular taste.
You and I have a similar taste there.
Okay.
We're not crushing 200 past.
I'm not interested.
Right.
And my sense about infrared sauna is that maybe I haven't seen the data,
is that a lot of people like it because they like the way they look in the infrared sauna.
It feels cool.
It feels like you're doing something unusual.
Now, infrared lights are beneficial for other reasons.
Actually, for mitochondrial health and the retinas, the good data.
But infrared sauna, to me, it never goes hot enough.
So I'm talking about 200 or hotter, maybe 180 to 220, obviously do what safe folks
and heat all the warnings about pregnant people not going in saas, et cetera.
I assume we're lumping in hot water immersion.
Hot water immersion.
So hot baths, hot sauna.
When would you like, when do you think most people could leverage sauna or hot baths
to benefit their training and fitness and health?
Yeah, okay.
I have a handful of things to say about this topic.
One of them is you never have a hard time convincing people to get hot.
Everyone feels good.
Like, yeah, getting a hot bath.
Like, can you take more hot showers?
Sure.
Like, no problem there, right?
There are a handful of studies that have looked at this immediately posts,
and it seems to even augment hypertrophy.
So after hypertrophy training, getting in the sauna for 20 minutes?
Yeah, whatever.
Whatever it needs to be.
We don't have a good titration.
What's the number minutes-wise?
We don't have a temperature titration.
Hot shower would be a week second best.
I would say it's a very week.
So take a hot bath.
I think a hot bath is probably a lot closer to what you're looking for.
it actually kind of goes back to our initial conversations theoretically you're just going to
aid in blood flow so you're going to put more nutrients in more waste product out metabolic stress
all that stuff is going through so but that's the thought anyways we far from knowing it's plausible right
absolutely plausible something people will do feels good um i let's say with cold and hot i want to caution
you against a couple of things this is true across all physiology but you need to be
really careful about moving percentages from molecular to outcome. Very careful. So, for example,
it's easy to see a paper that says, okay, we put you in a hot bath or something, and we saw
growth hormone increase 300%. That is not going to result in 300% increase in muscle size, right?
In fact, 300% might result in absolutely no change in physical size, right? So the reason I'm saying
this is because there's a lot of people in this space that will misapply the mechanisms.
And they'll grossly overestimate what these things can do and what they do do because they'll find
something like that. I mean, you know this. You've done enough cellular work to, in the lab,
if I see mTOR doubled, I think, shit, it didn't work. I need to see a 10x increase before
I know it's even physiologically relevant. So reading that paper, reading someone's social media
post, you're like, wow, it increased mTOR 38%. I'm like, well, I didn't work. And you're
like, wow, that's huge. I'm like, that's not 38%. I'm like, that's not 38%.
increase the muscle size. So that's a very important point I want to make because I'm going to
talk about the benefits here a second, but I don't want people to be fooled into thinking that
this is some crazy miracle. The same thing with the sauna. In terms of general health outcomes,
it is clearly a beneficial thing. This is a really good idea to get hot, a lot. It is not a substitute
for exercise, though. It's a very important distinction. If the options are nothing or sauna,
get in the sauna.
Really, really good idea.
If the exchanges, though,
I don't need to work out
because I did the sauna,
bad.
This is not a winning solution.
You and I know some maniacs
that actually work out in the sauna.
Oh, we do.
I don't necessarily recommend that.
That actually would probably kill
a large number of people.
But it can be worked up to.
Yeah.
It certainly.
Yeah.
So every time I talk about that,
I flag that
because it's just too easy to hear that and go,
oh, well, I think Dr. Huberman said,
if I just get in the sauna, I don't have to work out.
Like, no, no, those words have never come out in his mouth.
And I'm definitely not working out in the sauna.
If I'm in the sauna, I'm either sitting or I'm lying down
and I'm trying to make it through.
I tend to do three, 20-minute bouts
across the entire week.
So I aim for 60 minutes per week of heat exposure.
I would be lying if I said I've never worked out in the sauna.
Oh, so you're one of those.
Yeah, people will do air squats.
They'll bring the aerodym bike in there.
I look at the sauna as kind of,
of a time to get lazy and sweat.
Totally fine.
Going back to your question.
So potential to aid,
plausible aid,
we need to see more research
on that to really get a,
do I need to put this in practice.
I think if you try it,
very little harm,
I struggle to see a downside.
If you make sure your hydration's on point,
right?
Because now you got a factor in the fact
you just kicked out two or three pounds.
If you're at 200 plus pounds,
I assume, or roughly,
if you're in the sauna for 20 minutes,
I would imagine you can do two or three pounds.
Yeah, usually I'm,
I hover somewhere around like two or three pounds.
225. And I drink, I drink a 32 ounce. It's water with the electrolyte solution that's pretty
high salt afterwards and sometimes during. And sometimes after that, if I do it late in the
evening, I'll go to sleep and I'll wake up in the middle of the night. Just feeling so parched.
It's amazing how much water one loses in the sauna. Like a normal sweat rate for someone 225,
especially in 20 minutes in a sauna, I would absolutely expect you to do three pounds. Easy without like
I should be drinking more, even more water.
Yeah, you're probably half the water that you need to get.
And you mentioned the possible benefits of doing it after strength hypertrophy training,
which make sense for plausible mechanistic reasons.
No official data there yet.
What about after endurance training?
Assuming somebody hydrates well enough and they're not overheated from their endurance work,
could also be a benefit.
Yeah.
Wow.
So more and more, what I'm thinking the framework here is in an ideal world,
one would train and then do sauna.
or heat exposure of some kind,
endurance training or strength hypertrophy training
and then do sauna and then do cold exposure
on off days or at least four hours away
from any kind of training
or if you had to do it close to training
doing it before training.
Yeah, I love cold in the morning.
We've actually run this experiment on professional athletes
so we're doing out tracking with things like HRB,
which is a global metric of overall fatigue.
Okay, and you've probably talked about that before,
but problems with it, but roughly ideal.
of a raw fatigue.
HRV in general, higher the score, the better, right?
So low HRV is fatigue, right?
Well, if you wake up and take your HRV in the morning and then you get into ice,
what's going to happen is you're going to see that number plummet.
The second you get out, that's going to fall off the earth,
which means roughly you've moved into a sympathetic place.
Surprising, you get in 30-degree water, you're going to go very sympathetic very quickly.
However, if you continue to watch your HRV for 30, 60, 9,000,
and up to two to three hours post,
you will generally see an improved HRV score
relative to where you started.
So it's back to this hormadic stressor, right?
A really cold, shocking exposure
will be a net result of you being more relaxed
throughout the day in general.
And we've seen that now very consistently
across years with athletes.
So I think it's a great way to start your day.
You won't need nearly as much coffee
after spending three minutes and 30-degree water.
30 degrees is pretty darn cold.
I was in the ocean this morning for about three minutes.
It felt, I didn't bring a thermometer,
but it felt like somewhere in the low 50s.
But 15 moving is really cold.
Yeah.
Water's moving.
Yeah.
That's really cold.
That's right.
The thermal layer that surrounds you when you sit still in cold water immersion,
I'm encouraging people now if they really,
I was a joke that, you know,
people like to look real stoic and tough when they're in there.
Like they're just grinding through it with no pain at all.
But the stillness is actually reducing the,
the stimulus. If they sift around a little bit, you break up that thermal layer, that's where the
real action is. We've joked about this for years. Like, do 50 degrees with a whirlpool jet on,
now I'm impressed. Because that is hard. You sit in 35 degree for three minutes. But with XPT,
I've seen, I can't even tell you how many hundreds of people from all walks of life on all age that
we've been able to get in 30, some degree water for three minutes. 50 degrees with a whirlpool going,
that number gets very small. Yeah. And if you don't have access to,
Whirlpool, this should be reassuring to you.
You can, some people say, oh, you know, I don't have access to ice.
And ice can actually get pretty expensive.
You're doing a $50 ice pad every day.
So you can fill your bathtub with cool to cold water, get in, but just make sure that you keep sifting
your limbs and it's chilly.
Yeah.
And the studies on the very well established increases in dopamine and epinephrine that
occur in cold water exposure were actually done at an hour in 60 degrees Fahrenheit.
Yeah.
And so you don't necessarily need it ice cold or an ice cold.
bath. But immersion is really better than the cold shower. The cold shower is kind of a,
it's the, it's, it's kind of the espresso shot version. Yep. Yep. You know, it's sort of funny
because if you look at most of those initial studies and you think, man, how did they get people
to sign up to spend 45 minutes in 55 degree water? Fifty-five degrees is cold, even if it's not
moving and then they're going to not spend five minutes in them. They're going to go an hour.
If you've ever done ice bass at that temperature, you know, like, all right, after a few minutes,
it's not that bad. But man, that's a protocol.
Yeah, it's kind of an cold endurance protocol because one thing to get in for one minute to three minutes and you know you're getting out. You could sing a song. You could do anything to distract yourself. But 45 minutes to an hour is intense. Maybe they, I don't know, I don't think they paid the subjects. But anyway, that study was done in Europe. I forget where it was done. But anyway, they were they were hardy subjects. I want to talk a bit about overtraining and gauging recovery.
Yep.
So there are a couple methods that I've heard about and that I use based on some data that I've seen,
but mainly discussions with really informed people like yourself, Brian McKenzie, Kelly Starat and others.
The two that I'm aware of for gauging recovery of the nervous system and kind of systemic recovery are grip strength,
especially grip strength on waking in the morning.
Yeah.
And the so-called carbon dioxide tolerance test.
the ability to do a long controlled exhale after a few rhythmic deep breaths,
which I'm assuming taps into both one's ability to mechanically control the diaphragm,
but also how well one is regulating carbon dioxide.
First question is, is this stuff fiction, fact, or a combination of kind of anecdot, as I call it?
Are there any peer-reviewed published data?
Is your lab working on these things?
and am I deluding myself using these tools, or are they useful?
It's not fiction at all.
There are, like, CO2 tolerance, there's less published data.
We've run a study in our lab looking at the associations between the CO2 tolerance
and what we call it straight and state anxiety.
And those are in the publication process is what I'll say.
Great.
So you can't really talk about that stuff, as you know, until it's out.
But in general, I'd say, like, there's a reason I'm still doing it.
I'll just leave it at that.
Yeah, well, assuming it's not a clinical trial, I mean, I think sharing preliminary findings,
as long as we highlight them as preliminary.
I'm not a reviewer, but I look forward to reading the paper.
Yeah, but as you know, scientific, ethically, like, you need to be careful about
telling people results before you've gone through that process.
Right, which is why I'm flagging this as these results are not yet passed through
the peer review process.
So you're hearing about it prior to peer review.
Yep.
Having said that there's enough in that field.
I'm not the first one into that field.
And so I'm very confident that that's a real thing.
In terms of actual tracking recovery, the big picture is this.
When we run through a full analysis,
when we have an athlete go through our biomolecular athlete program,
we're going to run and we're going to look at three major categories.
Okay, category one are what we call visible stressors.
And then we have hidden stressors.
And then we have recovery capacity.
Any time the total stress load outpaces recovery capacity,
you're either going backwards in your physical ability
or you're reducing adaptability.
Now you have levers to pull here.
You can reduce stress intake
or you can increase recovery capacity, right?
What we want in an ideal situation
is to be able to implement the most stress possible
because that's the driver of adaptation.
Recovery from that.
Now we get the most adaptation.
An adaptation being simply a change,
whatever change you want to be.
That's our gold standard, right?
It's pie in the eye.
Some people have endogenous differences.
They just recover better.
they don't. There are genetic factors. But let's talk about the ones that are manipulatable.
If we go to the stress side of it, you want the throttle to be pushed as far down on the ones you
want stress from and as far off of the ones you don't want stress so that the adaptation comes in the
exact area you want and you're not burning gas and something you don't care about because you're
just, you're taking that total stress bucket too high. Recovery capacity over there. So here's how you can
do that. You can run some analytics and measure what we do with everyone through these very
comprehensive breakdowns to figure out what's that physiology look like hidden and visible,
and then what's the recovery capacity? Once we have that blueprint, we can now figure out what are
the two or three things we need to track that are these indicators of what we call performance
anchors. So an anchor is something that kind of drags behind you or below you that slows you down.
The analogy being, let's say we're going down one of these amazing canyon roads, and I won't
say which canyon we're in so you can stay hidden here.
And your car is going down at a certain velocity
And you want to go faster
Most people's first impulse is to hit the gas, the accelerator.
We want to push.
Well, that's fine.
But if your foot is on the brake
And you push the accelerator,
You might go a little bit faster,
but number one, you're wasting a lot of literal gas
To go a little bit faster.
And two, you're burning your engine.
You're going to blow.
The easier solution is just take your foot off the break.
You're going to go faster by just stopping yourself.
then if that's not fast enough, we can hit the accelerator.
Everyone wants to just push down, right?
More stimulus, more optimization.
Bing, Bing, Bing, Bing here.
Our first analytics are where are these performance anchors?
What's dragging you back?
What's putting down the brake?
I want to move those two or three things out of the way,
and now let's see how far you get.
Oh, look at that.
Your recovery capacity has gone way up.
Your adaptations are happening faster now,
or we can do more work because you're recovering quicker.
So we're trying to figure out in those buckets,
and we have a whole host of things that we measure biomarkers
and surveys and everything else that we go through
to find out what's there.
So after we've done that,
now we're just going to track a few of these recovery markers
along the way to figure out what's globally happening.
So that could mean grip strength.
I have some folks who are going to test grip strength daily.
Others, we're going to look at HRV or combinations.
We may look at performance metrics like a force plate.
So you're going to do a vertical jump every single day,
and we're going to see where that's at.
we've used the tap test before, which is how many times you can tap your finger as fast as possible.
It's a rough indicator of central nervous system.
In, say, one minute interval.
Exactly.
And there's just apps you can do on this.
Like you tap as fingers fast as you can.
It's going to say, hey, you did 60 taps today.
And your average is 75.
I like that because it taps into, no pun intended, into upper motor neuron capacity.
Because a lot of things like grip, like grip strength, obviously I have to send the deliberate signal to my hand to grip.
But at some point, the lower motor neurons are going to be taking over the majority of the work.
the signal is probably one and done, whereas the tapping is going to be repetitive sending of signals from upper motor neurons.
Yep. So some of the athletes I work with, we track blood every day. We track urine every day. We track
ideally a combination of subjective and objective measures. Everything from how did you feel last night to environmental sensors of their bedroom, full PSGs going on, running like actual sleep diagnostics, not an or ring, nothing against aura, but like full analytics.
Some of them, it's as simple as, how do you feel today? And what was your vertical jump?
Right? So we're going to put people in a position to succeed. We're going to figure out what's
a lever that they need to pull as well as what's their aptitude, what sport do they in, what can we realistically get away with. And some of them will take machines with them and we'll do blood every day and urine and all kinds of stuff. And some of them, it's a lot lower.
For myself, I'm not, as I mentioned before, I'm not a big fan of devices. I'm trying to wear the wristwatch. I tend to go off feel, which is not.
it's not the ideal objective way to gauge things.
But part of my reasoning for this is my colleague from the psychology department, Dr.
Alia Crum, has done some studies where they've deliberately given people false feedback about their sleep.
So told people you didn't sleep very well or they've told people you slept really well.
And performance can be driven in the expected direction based on feedback,
independent of how well people slept or didn't sleep.
Now, that doesn't mean you can take someone that only slept two hours or was up every 30 seconds because of apnea and tell them they slept great and they're going to perform great cognitive tasks.
But you can't take someone who slept very well, tell them that their recovery quotient wasn't very good and their output is going to be worse.
And that's my concern about a lot of devices out there, not to name specific devices, but it's still unclear to the general public what the specific algorithms are to generate these recovery scores.
right and so many of the things that reportedly track sleep aren't tracking sleep they're tracking
heart rate and breathing which are correlates of sleep depth but that's different and again I'm not knocking
those I think the sleep trackers if nothing else have provided a forum whereby people are very
conscious of getting good sleep it's sort of like knowing the total caloric intake of your food
people go wow I'm actually eating a lot more than I thought calibration or less in some cases but
often the case is that it's more so I think for the typical person
I'm wondering whether or not like myself, because I'm not a competitive athlete or certainly
not a professional athlete, competitive with myself, I suppose, but no one else.
Morning pulse rate I tend to take when I'm on waking. If I wake out of a really
stressful dream, I might relax a little bit and then just take my pulse rate, kind of get a range
and see if it's spiking for whatever reason. I don't tend to measure grip strength, although I've
heard you can just use a classic scale, old-fashioned scale with the Neil now old-fashioned
or some other more technical device is probably good.
If there's a low-cost one.
Yeah, they're all low-allocross.
And then the carbon dioxide tolerance test.
So we haven't really talked about that in specific ways.
My understanding of it is it's four deep slow breaths in through the nose, out through the nose,
and then a big inhale, that's max exhale, and then time duration of exhale through the nose,
and then stopping the stopwatch at the point where lungs are empty,
not necessarily as long as one could hold their breath.
Did I get that right?
Pretty much.
Okay.
And I guess we should credit you and Brian McKenzie.
Yeah, those guys.
Yeah, for sure.
And the folks under Brian's umbrella for really establishing this as a really good metric.
When and how can I use the carbon dioxide tolerance test to gauge recovery upon waking post-training session?
Would that be a good time?
Number one answer is, whatever you do, do be consistent.
So do it under like any good science experience.
do it under the exact same conditions as you can.
That generally means somewhere in the morning
because that's when you're probably going to have the most control,
most stability going.
So, yeah, like you would take any HRV or other metric,
wake up, get under control, get stabilized, take your metric.
Got it.
It's going to be pretty good.
Got it.
Sodium bicarb, baking soda.
Rumor has it and data has it
that it can actually be a pretty effective training tool.
Very effective.
Could you explain a little bit about how it works
and how one might explore using sodium bicarb to enhance training output in a couple of during context?
Yeah.
So there's a handful of these ubiquitously effective supplements for performance.
Sodium bicarbonate is one of them.
It's a very ingenious idea because it's so simple.
Effectively, muscle contraction happens because enzymatic function occurs within a fairly specific P.A.
range, right? So if it gets extremely acidic, it doesn't like it. And so whether you're running
through aerobic glycolysis or anaerobic or anything else, all of these things require, even ATP
hydrolysis requires ATPAs. An enzyme has to that. enzymes don't function well outside of this
fairly special range. So what happens is generally fatigue, the sensations of fatigue are actually
caused by some signal that, hey, we're starting to run out of pH, or we're getting in the wrong
the range. You're not out of gas, usually. You're not too low on oxygen. You're not running low on muscle
glycogen yet. You're typically going to see signs or feel signals of fatigue way prior to that,
mostly being pH issues. That being said, what if we could regulate pH better? Enter bicarbonate,
right? So without going too far into metabolism, effectively what happens is you take an inhale and you're
mostly breathing in oxygen, O2. When you exhale, you're breathing out CO2. So the difference is
you've gained a carbon somehow. Well, all of your carbohydrates in your body come in the form of long
carbon chains. In fact, that's what a carbohydrate means. It is a one carbon molecule that has one water
molecule attached. It's a carbon that has been hydrated. In the case of like glucose, blood sugar,
it's a six carbon molecule, right? In terms of fat, which are the only two places you're going to
get most of your cellular energy, carbohydrates and fat, that is also a big long block and chain of
carbons. So whether you're getting your energy from fat or carbohydrate, you're going to split
those atoms. So in other words, you've got six carbons attached to each other. And in this part
of chemistry, it's exergonic. So when you break that carbon bonds, so break one of those
carbons off from the other, that's going to release energy. Just like if you had a pencil in here
and I snapped it, and you go bang and pop. I broke the bonds that were connecting that
graphite, the next piece of graphite, and that released energy because I put energy into the
system, etc. Okay. As a result, though, we've now had, you know, say five or six carbons
chained together. We broke one off the end, which is not how it works, but making the point.
And now you have one free-floating carbon. You use that energy release to then go make ATP,
to then go make your muscles contract. But now you've got carbon floating around.
You can associate free-floating carbon with being at a higher acidic level. It's not going to
happen. The only way that you're going to go through this process is if your body says, do we have an
oxygen molecule available that we can bind this to immediately? Yes, we do. That carbon attaches to that
oxygen molecule. You can't just put CO2 in the blood because of what we just talked about. So you're going
to bind it through this bicarbonate process. It's going to go through your blood. It's going to go
into the lungs. It's going to go back into its carbon dioxide molecule. It's going to trans go through
the alveoli, into the lungs, and you're going to exhale. So you went from carbon to this bicarbonate
system back into carbon exhale. So inhaled, O2 plants go the opposite, by the way. So they're going
to breathe in the CO2. They're going to cleave off that carbon, stack those carbons together,
and that's how they get larger. In your blood, those six carbon chains are called glucose. If we
store that in your muscle, we call it glycogen. So we take a bunch of glucose and stack it
together in a plant, we call that starch. That's effectively what it is, right? So you take a bunch
of carbon from the atmosphere, stuck it all together, and that's a starch. If you want to do it in the
form of fruit. We take that starch like from the ground. You put it up through the tree,
go all the way up to the top, put it into the flower, break it up into these big, huge chunks
of starch, into little forms called fructose or glucose. That's why fruit has fructose in it,
and that's why tubers and stuff have starchin. Basically, starch in an animal, it's glycogeninous.
Okay, all that to say, if that's happening, and we know that a byproduct, specifically of
anaerobic glycolysis, meaning the breakdown of carbohydrate,
for fuel, typically in a very fast pace with low oxygen availability, the downside of that
equation is acid production. We know that that's a problem because I started the conversation
off there intentionally. So what if we could reduce the acid buildup? Now, you know how pH kind of
works? I went and kind of double negatives there, right? You don't want too much acid buildup.
Then could we prolong and sustain energy in a more effective pace, especially in this anaerobic,
interval kind of environment.
And again, that's important
because in those things,
failure is not a result
of running out of fuel
or oxygen.
It's a result of fatigue building up
way too quickly.
Is that also true
for resistance training?
There's maybe more of the
creatium phosphate system.
That can be an issue.
It could simply be an issue
of force production.
You just don't have enough force.
At least you're not out of energy.
You just can't muster enough force.
You do enough reps,
then it's going to be an issue there.
Creatine phosphate would be the big winner, depending.
So to come back a little bit to the beginning,
and then I'm circling this all together intentionally.
All right.
Well, the way that we produce energy
is going to be in two primary categories,
anaerobic and aerobic,
aerobic meaning with oxygen, anaerobic, meaning without.
In terms of muscle contraction,
you're pretty much talking about carbohydrates or fat.
Now, fat is going to be exclusively aerobic,
meaning I'm going to use fat from the entire body.
roughly equally. So you're doing a sprint up a hill and your hamstrings or your glutes or your
quad are on fire. You can't, you're not just going to use the fat that's directly in those hamstrings.
You're going to lose it from the entire body. It has to go through liposis, so it's in this stored form
in adipose tissue. It's got to get broken down, put into blood. Blood's going to have to go through
your body, get taken up into muscle, taken up through muscle into the mitochondria.
Then we're going to have to go through this process called beta oxidation. So remember,
carbohydrate and glucose especially is a six carbon molecule.
Fat, if it's in the form of a tri-glyceride,
it is a three-carbon glycerol backbone and three, you know, tri-one, two-three,
fatty acids.
Three-carbon backbone, and those fatty acids are just big, long chains of carbon.
That's all it is, right?
So we're going to break that thing down, put it in the blood, move it up,
move it into our mitochondria.
You can't walk those things across the mitochondria wall.
They're too big.
So what you have to do is cleave them off in a little,
chunks, and it turns out we break them off into two carbon chunks, so we call it beta, as in two,
move those into mitochondria. That can go through this little thing called crep cycle or trixilic
acid cycle, and you kick out a bunch of energy out of that. You had two carbons, so as a result of
that process, you're going to generate two carbon dioxide. But remember, you can only go
through that process if oxygen is available because you have to be able to place those carbons onto
something, or acid gets up way too high, too fast. This is one of the reasons why fat is a nice
fuel source, but it's very slow. It takes physical time to move from the back of your shoulder
into your blood, down your hamstring, uptake, uptake, uptake. In addition, it's required oxygen
availability. If you need energy faster, you simply don't have the time to bring in the oxygen,
transport it through, go through capillaries, exchange through tissue, etc.
Carbohydrate, on the other hand, is going to be stored locally in the exercising muscle cell,
and specifically in the cytoplasm. As glycogen. As glyc, yeah,
as glycogen in the stored there.
So what's going to happen initially,
your initial demands for fuel
are going to come from the glycogen stored
within the muscle fiber itself.
It's just going to break right there.
And you're going to be off the races.
So you have the six carbon molecule,
you're going to break it into two separate three carbon molecules.
Okay, boom.
That breaking provides you a tiny bit of energy.
Very small, but some.
Now you're going to take those two, three carbon molecules
and you want to be able to oxidize them
because that's your only next step.
But in order to do that,
you've got to go those into mitochondria.
So you've got to break
one of those molecules off.
So then you'll be back to your two-carbon molecule,
just like you did with fat.
That's going to go into mitochondria,
and then it's going to go through the exact same Krebs cycle,
two-carbons, et cetera.
But hold on, if you don't have sufficient oxygen
or sufficient mitochondrial availability
and you're stuck at that two, three-carbon place,
what do you do?
You have problems, right?
Now we have to say, okay, wait a minute.
we have a three-carbon molecule and we have a bunch of this acid build-up now acid functionally is
hydrogen that that's what pH potential hydrogen is what pH stands for right so if hydrogen is
building up as a byproduct of muscular contraction and then you're having this three-carbon molecule what
it can actually do is grab one of those hydrogens and those three carbon molecules by the way are called
peruvic acid right if you take the peruvic acid and you grab hydrogen put it on top of it we now
have a different name for it. It's called hydrogen peroxide. Lactate. Bingo, right? That's what
lactate, a lactic acid is, right? So we've now built that up. So number one reason why lactate's
not causing your fatigue. It's actually preventing it and that it does a bunch of other really cool
stuff. But the point is, that system can only last so long. That gets overwhelmed very quickly.
What are you going to do with the rest of this hydrogen? Well, if you started off in a normal pH range,
you don't have very far to go
before you've now gone into
that level of too much acidity.
If you start off in a more basic
and basic, I don't mean simple,
I mean chemistry, right?
And more alkaline.
Then that same amount of increase in pH
is no longer,
now it just put you back in your physiological range.
So sodium bicarbonate,
whether taken as a cream
or a powder or baking soda
or anything else,
can simply put you in a more alkaline state
even acutely.
So this is something you can take
right now before your workout.
You're going to delay,
what we call delay the progression of fatigue.
And how would people start to approach this practice?
My understanding is you can do this with common, you know, store-bought baking soda.
No question.
There's always a concern about gastric distress.
That it's a very effective laxative, sometimes an unwanted laxative effect.
But how would one approach this before?
Let's say I'm going to, I'm doing the mile repeats exercise.
mile repeats protocol that we talked about earlier.
I'm doing that for a few months,
and now I want to try the sodium bicarb approach.
I'm well hydrated.
Hopefully I'm well rested.
I'm ready to go.
When am I going to drink this sodium bicarb solution?
How would I make the solution?
Let's say I take 10 ounces of water.
How much bicarb do I want a sodium bicarb should I put in there?
Can we come up with it?
Is it half a teaspoon?
Is it a teaspoon?
Here's what I'm going to tell you.
You will thank me by starting,
lower. You can always go more later. So a little pinch. You cannot go backwards. How about I
start with a quarter teaspoon? Fine. Half is fine. Half a teaspoon. Totally fine. Dissolve that.
Slug that down. I read a study recently that showed that people will hit their, the peak benefits of
this at different times, but it's somewhere, if memory serves me correctly, somewhere between 60 and 90
minutes later. So I might want to drink it on the way to the track? It can. It can be as low as
20. Okay. So maybe as I get to the tracks, since I'm going to do some warm up with some
walk and jogging. I say 45 minutes. Okay. That's just a very rough standard. But yeah, you're right. It is,
individualized. And you probably want to play with that a little bit, if not just somewhere in the
neighborhood of 20 to an hour. Okay. And then the perceived and real fatigue, if done correctly,
the perceived and real fatigue ought to be reduced. Yes. I can do more work without feeling exhausted.
Will I feel less of a lactate burn? Yep. Done in air quotes for those listening, I realize that's a
very crude way to describe a complex physiological process.
Fantastic.
Can sodium bicarb be used repeatedly for longer duration training?
Yep.
And if I were going to use it with weight training for whatever reason.
Maybe I'm doing circuit type training or I'm doing the superset type strength training that you
talked about before, push pull, push pull, where it's a little bit more cardiovascularly demanding.
Then maybe I'd sip that throughout the workout, make sure there's a bathroom nearby.
It sounds like.
Because I am aware that many people get pretty serious gastric distress.
It can happen very quickly.
Okay.
Great.
Well, it sounds like an amazing training tool.
I really appreciate you sharing it because I think it's one that doesn't get a lot of airtime these days because it's been around.
But sounds like it has some pretty impressive effects.
Yeah, you know, it's sort of funny about that is.
I mean, I get it.
Pop culture is what it is.
But still to this day, if you want to talk about sort of your most effective general health slash performance supplementation,
it's the same three to four to five.
It's because they work really well.
Without going into the chemistry of each one and the practice, each one,
because I definitely want to get you back to talk about nutrition and supplementation at some point.
But I think we need a full couple of hours to get that right at least.
As a teaser, would you mind just listing off the other supplements that you have found
are very effective for many people?
So sodium bicarb or baking soda is one.
What are some of the other ones?
Yep, we'll go kind of a reverse order.
Beta alenine is another very classically effective one.
Similar idea, assuming by carbon.
So it's going to,
beta aline is going to come in,
it's going to be converted and stored as what's called carnacine
in the muscle.
And carnacine is an intracellular buffer.
So in other words,
it's just going to delay the buildup of acid.
So fatigue blocker, if you will.
So very effective, very cheap, very safe,
well studied.
The top one, though, of all of them, by far,
that has an incredibly strong,
profile. It has, it is a cheap, it is a simple form to get, has a important magnitude of effect,
and is effective across multiple domains of physical health and performance. And it is,
because of that, it is my crown jewel. It is, in my opinion, without question the Michael
Jordan of all supplementation. And that's creatine monohydrate. It affects so many things. We typically
think about it as its muscle stuff, right? You talk kind of, quickly we're talking about the creatine
phosphate system. But we have to realize the mass majority of research on creatine phosphate is not
in support performance and has not been for 20 years. It's in clinical. And it has everything from
effects on the neurological system to there have been associations to mental health and depression.
And to be very clear, I am certainly not saying you can take creatine and cure anything. And I'm
not saying it's going to stop you from depression or anything, but I'm saying there's a lot
of research in these areas and there's a reason people are doing it.
I completely agree.
And if you're willing, I'd love to have you back
for us to do a discussion on creatine and the brain
or creatine in the nervous system.
That would be a lot of fun.
And maybe we can do a kind of a journal club
in advance of that.
For those that don't know, a journal club is where
scientists read a bunch of papers and then argue about them,
discuss them, and try and extract the kind of agreed upon center of mass,
if you will.
I think I've long been taking five grams
of creatine monohydrate per day, mainly for the cognitive effects.
I sense an effect.
That's obviously the annex data,
but I think there are a lot of data out there as you believe in too.
There's enough.
You're not crazy.
There's enough there.
And in fact,
there's enough mechanism now to understand the metabolic needs.
People think the metal,
I'm a muscle guy, right?
So I'm going to think about the metabolism needed to fuel muscle.
But we forget cells, immune cells, red blood cells,
nerve cells, astrocytes, brain,
all this stuff requires energy.
And it's all going through metabolism.
It's super interesting. We will do the deep dive on that soon. I have a final question for you. You're involved in a really interesting, I think really cutting edge project that I first learned about from you. I don't know of anyone else doing anything as forward thinking and frankly as relevant to the general population because of my interest in people getting better sleep and learning how to do that, avoiding stress and learning how to do that.
tell us a little bit about what I believe is called absolute rest.
Right.
So this is something that we've been playing with behind the scenes for a long time.
And this is typically how high performance stuff works, right?
People want exclusivity.
And so this has been built.
Effectively what happened is a friend of mine, Cody Burkart.
I don't know if you know Cody, but a famous.
Down in Texas.
Yeah.
Yeah.
NASA.
NASA guy.
Yeah, I do know Cody.
Wonderful.
Just down the road thinker.
everyone's interested in sleep, right?
And for forever I would say, I'm going to use it with athletes,
but everything available tells you how you're sleeping.
Nothing can tell you why you're sleeping that way.
And so we got together in Boulder,
and then I met some of his former colleagues,
computer science folks, Harvard MD,
and some really impressive tech folks.
And we were just thinking about an idea,
and we came up with,
and we started to realize the problems, right?
We use first principle thinking.
It's one of my favorite approaches.
If you're not familiar with that, go Google that.
Like, that's just a recipe to solve problems, this first principle thinking.
And we just started to think about, like, man, all the sleep tech is there.
It's real.
I don't need to convince people that they need sleep.
Everyone's done that.
You need high quality sleep.
But how can I provide solutions?
And with the people I work with, I can't just tell them your testosterone's down or your sleep's down or recover.
I need to be able to be like, this is down and here's why and here's our solution.
That's how our high performance world works.
So enter absolute rest.
This is saying, okay, what are the actual nodes that go into high-effective, high-quality sleep?
Number one is psychology.
So there has to be some sort of screening diagnostic for,
are you not sleeping because of simply you can't control yourself?
And you've done a wonderful job of giving people tools.
Or if you can't quiet your mind before sleep, do this.
If you wake up and you can't go back to sleep, here are a bunch of things, right?
So we have some screens that we can do, and there's some of other stuff we can do to analyze.
this is a psychological issue. Let's say it's not. You're under control and we have different tricks we use
and stuff on Jim Hack we talk about, but it's not that. Okay, is it physiology, which is no number two.
Do we know what your dopamine levels are like? Do we know what your serotonin levels are like? What's melatonin look like?
What's adrenaline? What's cortisol? Cortisol being the primary driver? What is this relationship, DHA? Where are these things at?
So we're going to measure all that and track that. We're going to measure that during the day,
prior to sleep, we're going to measure that next morning
and even sometimes throughout sleep.
And we're going to figure out this is a physiology problem.
If it is, then we have clear corrections.
If not, we're going on the next step,
which is, is this possibly a pathology?
So you have some sort of sleep disorder.
We're going to run full, what's called PSG,
so polycytrography, the exact same stuff you would get
in a sleep clinic.
It's a sensor that's going to go on measuring EEG and EOG,
and we're going to have muscle activation sensor
to see if your legs are moving
and everything else is going on.
And we're going to get a full diet.
And if anyone's ever done this, the amount of sleep issues that are happening in people that they don't even realize is extraordinarily high.
So we're going to figure this out. One very quick example. We just did this with a professional athlete.
And he was having like 280 roughly of these episodes per night. And to be categorized as an episode, you have to meet these four specific criteria.
Oxygen saturation, ventilation changes, brain changes, et cetera. And he hit that over 280 times a night.
and what this technology allowed us to do is figure out what position did all these things occur in.
Well, in his particular case, most of them were happening was on his back. And so we bought a very simple
like pillow, basically, that went on his back that kept him from sleeping on his back. And we saw an 85%
reduction in sleep awakeness issues the very first night. Now, we did that. Testosterone eventually
tripled after three months by just improving sleep. And all we did is move him on to his left or right side.
So huge improvements just by understanding where the problem occurred and why it occurred there.
We didn't have to change hardly anything else.
He had the basic hygiene stuff down and temperature and all that stuff.
And he had his chili pad and all that to keep the thing cool.
We couldn't fix it.
Years, by the way.
This took us two years of just trying everything.
We're like, man, and it was just like, I wish, we could get you to sleep better.
And I pulled out every trick I knew.
And it's just as soon as we built this dinner, I'm like, oh, my God, it's all.
he's not overweight by the way he doesn't have any he's not iron deficient isn't have any of these other
classical symptoms that are associated with badsy supplementation everything we've done a thousand
protocols that fixed it overnight so if it's not psychology it's not physiology and it's not pathology
then the last one that people don't have any idea about is environment and so what you don't realize is
we have a box we can sit right next to your bed you just plug it in you don't have to do anything
and it's going to run full environmental scans so it's going to look at the temperature in your room
It's going to look at the humidity in your room.
It's going to look at the volatile organic acids.
These are things that are seeping out from your mattress.
It's going to look at particulates in the air and possible allergens
and things that are floating around that are closing your nose off
so you can't sleep at night and now your mouth breathing and you've talked a lot.
I'm sure on the previous episodes about why that's bad.
It's going to look at your CO2 cloud.
So we've talked about we've already set this point up, right?
You're inhaling O2, but then you're exhaling CO2.
Well, during the day and when we're conversing,
you have quite a bit of force with that exhalation.
right but at night it's just barely seeping out of your mouth so what happens is CO2 sends to
cloud up and build around your face and then you end up rebreathing that CO2 and this can cause a large
number of sleep problems because you're simply re-breathing in the panic whether you fully awake or
just kick out of a sleep stage the CO2 around your face is a big issue this stuff has all been
known by the way with the astronauts for a very long time it just hasn't translated into the
to the commercial spaces of course gone to our high performance
former space. So we can measure that as well. And then we can figure out, like, for the most
extreme, we can actually come into a bedroom and build an entire sleep optimization set up and
control the entire thing. But for most folks, the minimum we can do is run full of diagnostics
and check off. Is this environmental related? Is it pathologies? Is there something else?
So is this a commercial device that people can eventually access? It is now.
So where can people learn more about absolute rest? Absolutelyrest.com.
Very cool. And just for full disclosure, I wasn't aware that you had done this prior to today. You mentioned I was like to ask people, scientists or otherwise, I always love to ask you, what are you most excited about lately? And it sounds like an amazing technology. And just to be really clear, that's not like something we're working on. That's landed. We're ready to go.
Great. Well, that's one of the things I appreciate about you is that you're willing to sometimes speculate, but you always say it's speculation. But in general, you're, you seem like the kind of guy where if you're going to be public facing about something, if you're going to make a statement, there's got to be quite a bit behind it. You're not going to allude to the in 10 years we might be able to do this or in five years. You're a very data-driven kind of guy.
Yeah. Well, the people I work with, we need answers. Right. We don't have that time frame. And we typically have like, hey, we start the season in four weeks.
So that's just where I'm at.
Well, as I said, I appreciate that about you, but it is, but one of the many things I appreciate.
I think the listeners and I can well appreciate on the basis of today's discussion.
What a enormous wealth of information you are, how clear and potently you communicate that information.
And also, you can take a huge cloud of information and still distill it into protocols that ought to
to work for 75% of people, 75% of the time, which is an immensely valuable thing to do.
So for me and from the listeners, I just want to say thank you so much for taking the several
now hours. I lose track of time, which reflects all good things, several hours to take a break
from teaching, take a break from research, take a break from the other important commitments of your
life and really share with us all this incredible information. I'm so, so grateful.
My pleasure, man. I'm glad we finally got to connect. This has been a long time in the making.
It has. And I'm going to bring the breathing protocols to my training. I'm going to start doing more of the endurance type and interval type training. I'm going to start moving when I do heat. I'm going to start moving when I do cold. I might even start throwing some sodium bicarb into a very small amount of sodium bicarb into some water before I train. And listen, Andy, Professor Andy Galpin, thank you ever so much.
My pleasure.
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