Huberman Lab - GUEST SERIES | Dr. Andy Galpin: How to Build Physical Endurance & Lose Fat
Episode Date: February 1, 2023This is episode 3 of a 6-part special series on fitness, exercise and performance with Andy Galpin, PhD, professor of kinesiology at California State University, Fullerton. He explains protocols to im...prove the various kinds of physical endurance: muscular endurance, anerobic capacity, maximum aerobic output, and long duration endurance. He also explains how the body uses different energy sources (carbohydrates, proteins, fats) during rest and exercise. He also explains the mechanisms underlying fat loss and how and why exercise accelerates rates of fat loss. We cover the many concepts related to endurance training and fat loss such as metabolic flexibility, breathwork training for exercise performance and recovery, lactate production and regulation, how to improve blood flow to muscles, anaerobic vs. aerobic metabolism, exercise fatigue, low-carbohydrate diets and fat loss, and how to combine different types of workouts to improve overall endurance. This episode in intended for everyone ranging from novice and recreational exercisers to elite endurance athletes. Anyone wishing to improve their physical health and performance stands to benefit from the information. For the full show notes, visit hubermanlab.com. Thank you to our sponsors AG1 (Athletic Greens): https://athleticgreens.com/huberman Levels: https://levels.link/huberman LMNT: https://drinklmnt.com/huberman InsideTracker: https://www.insidetracker.com/huberman Supplements from Momentous https://www.livemomentous.com/huberman Timestamps (00:00:00) Endurance: Benefits, Mechanics & Breathing (00:07:30) Tool: “Exercise Snacks” (00:14:21) Sponsor: Levels, LMNT (00:18:01) Endurance Categories (00:22:16) Fat Loss & Respiration; Carbon Cycles & Storage, Metabolism (00:33:08) Exhalation Rates, Exercise & Fat Loss; Calories (00:41:47) Cardiovascular Adaptations, Cardiac Output & Maximum Heart Rate (00:47:03) Sponsor: AG1 (00:47:55) Excess Post-Exercise Consumption (EPOC); Exercise Intensity & Fat vs. Carbohydrate Energy Utilization (00:59:35) Tool: Training for Fat Loss, Carbohydrate Stores, Liver Glycogen & Fatigue (01:08:01) Metabolic Flexibility, Carbohydrates & Fat; Exercise & Flexible Fuel Utilization (01:16:07) Muscle & Basal Metabolic Rate (01:19:40) Sponsor: InsideTracker (01:20:43) Assessing Metabolic Flexibility, Blood Glucose, Carbohydrates (01:27:48) Caffeine, High-Carbohydrate Meals & Timing, Managing Daily Energy (01:36:42) Cellular Energy (ATP) Production from Carbs; Lactate; Anerobic, Aerobic (01:50:45) Lactate, Energy Production Buffer (01:53:14) Fuel Sources & Exercise; Mitochondria, Oxygen Availability & Lactate (02:02:50) Lactate for Exercise & Cognitive Performance (02:04:33) Energy Production, Waste Management & Endurance Exercise; Insulin (02:12:49) Protein & Fat Utilization for Energy; Exercise & Fat Loss (02:21:20) Protein as Fuel Source, Fire Analogy (02:26:39) Low-Carbohydrate Diet & Performance (02:29:40) Muscular Endurance: Fuel Sources, Training & Capillarization (02:37:30) Tool: Muscular Endurance & Modifiable Variables; Examples (02:45:07) Anerobic Capacity: Fuel Sources, Training & Oxygen Utilization (02:49:23) Tool: Cardiac Output, Heart Rate Zones & Breathing “Gear System” (02:58:10) Tool: Anerobic Capacity & Modifiable Variables; Examples, Nasal Recovery (03:11:45) Tool: “Sugarcane” Endurance Protocol (03:14:02) Anerobic Capacity, Training Progression (03:16:40) Tool: Maximum Aerobic Output, Training & Modifiable Variables (03:21:58) Tool: Long Duration Endurance, Training, Circuits (03:25:13) Long Duration Endurance, Capillarization, Fatigue & Breathwork, Technique (03:29:10) Weekly Combination Training, Metabolic Flexibility & Longevity (03:37:23) Tool: Mixed Endurance Training, Half Marathon Example (03:47:33) Zero-Cost Support, Spotify & Apple Reviews, YouTube Feedback, Sponsors, Neural Network Newsletter Title Card Photo Credit: Mike Blabac Disclaimer
Transcript
Discussion (0)
Welcome to the Hubertman Lab guest series where I and an expert guest discuss science and science-based tools for everyday life.
I'm Andrew Hubertman and I'm a professor of neurobiology and ophthalmology at Stanford School of Medicine.
Today's episode is the third in the six episode series on fitness, exercise, and performance.
Today's episode is all about endurance and fat loss, that, the specific protocols required to achieve the four different kinds of endurance
and how to maximize fat loss. Dr. Andy Yalpin, great to be back.
Today we're going to talk about endurance. And I'm very interested in this conversation because
I like many other people strive to get a certain amount of cardiovascular work in each week.
Maybe a long-ish jog, maybe a swim,
ride the bike, etc. But when I think about the word endurance, the idea that almost immediately
comes to mind is about doing something for a long period of time repeatedly. But I have a feeling
that there are other ways to trigger this adaptation that we call the endurance adaptation.
So I'm excited to learn about that.
I'm also excited to learn about the fuel systems in the body that allow for endurance and
other modes of repeated activity.
So in order to kick things off, I'd love for you to frame the conversation by telling
us what is endurance and are there indeed a large variety of ways to induce
what we call this endurance adaptation?
Sure, the way I wanna start actually here
is calling back to some of the things
we talked about in our previous conversations,
which are really, people exercise for three reasons.
Number one, you wanna feel better.
Number two, you wanna look a certain way.
And then number three, you wanna be able to do that
for a long time, right?
So you need the way that we say it in sports
is look good, feel good, play good.
Right, so I want some sort of functionality
to be able to perform a certain way, whatever that is for you.
You want to be able to look a certain way
that whatever that matters for you.
And then you want to be able to do that for a long time.
So when it comes to endurance,
we have a bunch of misnomer's here,
which is the same thing with the strength training
of resistance exercise side,
where we wanted to dispel this myth that,
I lift weights only because I want to gain muscle
or play a sport, and I want to do cardio
because I want to lead their loose fat
or for long health sake.
And just like we smashed that myth
from the strength training side,
I want to smash it from the endurance training side.
There are so many other reasons
that you want to perform endurance training.
Regardless of your goal, whether it is longevity, whether it is performance, or whether it is
aesthetics.
So I want to cover all those reasons exactly what to do, protocols, of course, and why
those things are working that way.
In general, though, the quick answer is, really endurance comes down to two independent
factors.
Factor number one is fatigue management,
and then factor number two is fueling.
And that's all that really comes down to.
So all the different types of training
are going to reach a limitation,
which are either again, your ability to deal
with some sort of fatigue,
and that's generally a fatigue signal.
The other one is managing some sort of restriction of energy input.
And a lot of the, what they're here is a lot of the times people think it's a fueling issue
and really it's a fatigue management issue or the opposite.
And to have a complete health spectrum, regardless of whether you're a high performance athlete,
like I typically deal with or general public, you need to be able to do both. Manage fatigue as well as understand fuel storage. So that's really what we're going
to get into today. Fantastic. I can't wait. Before we dive in, I'm going to ask you what I often
ask people who are expert in their respective fields, which is, is there any non-obvious tool
Is there any non-obvious tool or mechanism or tool-end mechanism that can allow people to access better endurance?
When I think about training for endurance, again, I think about trying to run longer and
longer each week or swim further and further and so on.
But I do wonder whether or not there are other forms of training that can amplify the endurance
adaptation that I or most people perhaps don't think of as endurance.
Sure.
The way I want to answer this is, if we look back and think about how we've answered that
question with power and strength and force production, it is really about how much can
you produce maximally once.
What you're asking now is how can I repeat
that same quality of performance?
If that's the case, endurance really comes down
to your ability to maintain proper mechanics.
That's going to, like, the biggest way we can increase
your endurance exponentially very quickly is mechanical.
And this is starting with breathing.
And so we need to be breathing properly.
We need to have proper posture and positions.
And then we need to be moving well.
Efficiency is going to trump force.
Always for endurance.
The other side of the equation is not that you can have a little bit of leaks in your
mechanics and still squat well or jump high
and be fine because you don't have to suffer those consequences repeatedly.
That's going to drain you over time.
The quickest way to improve endurance is to improve mechanics.
Mechanical thing I would go after first is your breathing techniques, your pattern, your
entire approach, as well as your posture.
Then from there, the third one would be your movement technique. Is it possible to describe the best way to breathe
when doing endurance training, or is it far more complex than that?
And if it is far more complex than that, then certainly we can get into it
during today's episode.
Yeah, it is. Both of those, I will give you a quick answer, though.
A lot of the times you can kind of hit the cheat code, which is nasal breathing.
There's plenty of times when you don't want a nasal breath,
you don't need to nasal breath.
But just again, is that like a one tool that is a pretty
general answer.
If you can do that, a lot of the times that will fix
breathing mechanics just by default.
And we can maybe talk about why that is later.
But that would be my sort of one sentence bullet point
answer immediately of how to get in the right position.
So second one would be simply looking at your posture.
So whether you're on a bike or you're doing a lift
or you're running, if you're literally hunched over
and your ribs are touching your femur
or getting closer and closer,
like tends to happen on a bike or an aerosol thing
for somebody I've seen recently.
This morning I was on the assault bike,
doing a sprint and I asked Andy, Dr. Galpin,
to critique my form and anything else he wanted to critique
so that I could improve.
And he did comment on my rather sea shaped posture.
I'm encouraging me to be more upright,
which I should probably do now as well.
And he also queued me to the fact that
during a one minute sprint,
there is something that is quote unquote magic that happens right about the 42nd mark.
And I use that as a as a milestone to look for and indeed something does happen at the 42nd
into a one-minute sprint where all of a sudden it does seem to get much easier for reasons
I don't understand. Maybe you can tell that but it certainly had nothing to do with my
posture. My posture needs improvement.
Yeah, well, yeah. So, breathing mechanics and breathing strategies, people tend to be
over breathing early on, and this is going to lead to problems later. So having a more
strategic breathing pattern and approach is, again, a very quick solution.
I know that we are going to dive very deep into the mechanisms
of energy and metabolism and endurance today,
but as long as we're having a discussion
about these brief tidbits of how to improve endurance,
are there any other ways to improve endurance
that are of relatively short time investment,
even if they require a lot of energy.
Sure.
The classic paradigm you're gonna find here
is steady state-long duration,
posed up against what a lot of folks will now call higher
intensity interval training specifically.
And there's a lot of misconceptions here.
The quick answer is you need to be doing both.
And there's probably a bunch of stuff in between
that you should be practicing.
If you honestly wanna to maximize those three factories
we talked about at the beginning,
you need to be training across this full spectrum.
Just like I told you to train across the full spectrum
of your lifting, we wanna be doing the same thing here.
So are there independent special factors
that can happen with the shorter time length,
higher intensity stuff?
Absolutely.
There's also magic that happens on the other end of that spectrum. So it's very important that people don't just choose
one side because what tends to happen is people either go with all I'm going to do 30 or
45 minutes of steady state stuff, that's it, or I'm going to do the opposite, which I'm
going to lead that stuff on the table, not do it because I only want to do high intensity
intervals because I can get it done in five minutes. So there's magic on both sides of the equation. We want to get into all that. But just to answer
your question directly, there's a whole bunch of things you can do in under one minute that are
convenient to do. And there's a wonderful set of papers out of a couple of laboratories in Canada
that champion this idea that's called exercise snacks. So there's a bunch of, there's a series of studies that have been done here that are
really interesting and that they've looked at a couple of things that are noteworthy.
One of them is a 20 second bout of all-out work and this is actually done in workers in
an office and so what they had them do is run upstairs and I believe it was about 60 steps
is what it took them.
Something along the order of 20 seconds exactly.
And they repeated that about once every four hours.
So really you go to work, you get, you know,
put your coffee in your bag down, whatever,
you run up a flight of stairs, 20 seconds later
then you go right back to work at lunch
and then before you go home, you sort of repeat it there.
And if you repeat that, that's multiple times a week,
you're gonna do that.
I think they, in one of the interventions,
it was three times a week for six weeks.
18 total times, you did that.
And what you'll see is a noticeable improvement,
and this is statistically significant improvements
in cardiovascular fitness, specifically VO2 max,
as well as a number of cognitive benefits,
work productivity, et cetera.
That can happen in as little as 20 seconds,
you don't have to go to the gym. You don't have to shower.
You don't have to do anything like that. Just find the stairs.
Run up and down them a few times. Now you may have noticed
you actually sort of caught me yesterday. I did that right here, right? I was just I
We had a little bit of a break. I was feeling an energy law. I ran up to stairs three or four times
Felt a lot better. So that can actually also help.
They ran another study
where they looked at that following a giant
high glycemic index meal.
And what they saw, and then they took insulin measures
and a whole bunch of other biological markers associated
that you want to be paid attention
with the high glycemic index meal.
And they looked at those immediately
an hour, three hours, six hours as a post.
And it was very clear that same intervention
was able to improve post-planned gluteus control insulin
and a whole bunch of other factors in addition to that.
So if you are the sort of type who's like,
wow, I'm in an office all day,
maybe also how to giant high glycemic index meal,
not the best approach, but a little bit of mitigation
there can just be running up a flight of stairs or doing something like that for as little
as 20 seconds.
So there's a lot of magic and power and maximal exertion.
If one does not have access to a flight of stairs at work, could they do jumping jacks?
Absolutely.
I mean, you could do anything you really wanted.
It's not the mode of exercise that matters here.
It is simply the exertion.
You just get up as hard as you can.
You could do burpees.
You could do any number of things.
You could sprint down your road,
down the hallway back and forth.
The mode is just something that was easy
for the scientists to control.
And X number of steps, people could do it, you know, to fall, hurt yourself, things like
that.
Just to remind me, it's once every four hours, one minute of all of 20 seconds.
Oh, 20 seconds, excuse me.
20 seconds of essentially all-out exertion while remaining safe, not going so fast up
the stairs or doing jumbo jacks.
And certainly not down the stairs up the stairs, please.
escalators don't count. Well, I suppose they count if they're,
you know, if you're moving, if you're not remaining on the same steps,
in fact, in an airport recently, I saw somebody walking against the,
oh, they're the conveyor while talking on the phone while waiting for their flight to take off.
I thought it's genius, right? It looked a little awkward. Who cares? Yeah, but it was. I have looked
awkward in every airport. I've been in for the last 15 years for these exact reasons doing wild stuff
like that. Yeah, well, nothing's more awkward than not being able to walk to the end of the terminal
simply because one isn't familiar with walking that far carrying a couple of suitcases. There you go.
Yeah, that's the other fit test.
That's the case carrier.
Yeah, I'm in the airport.
I love this.
So once every four hours, 20 seconds,
so maybe once when arriving to work, once four hours in,
and then four hours, I must be a probably it works
somewhere, you know, eight plus or minus two hours.
Now, one thing I actually really want to make clear,
because your audience is so incredible.
They tend to be really excited about these protocols and they follow them exactly as written.
That's not exactly how science works. So it doesn't necessarily have to be every four hours. It's
not half to three times a day. It doesn't have to be 20 seconds. They literally built that protocol
because it was trying to replicate a real life scenario. Maybe you're in an office building,
you're generally there for eight hours.
Let's see if you did one every sort of,
so if you wanna do it four times a week,
great, if you can do it only 10 seconds, amazing.
You're probably going to get the same benefits.
Those are not the details to pay attention to.
The detail to pay attention to is every so often,
multiple times a day, try to get your heart rate up
really quickly.
Doesn't require sweating, doesn't require anything else, there's no warm up associated
with it.
Again, you need a minute break in between meetings or whatever and you can sprint up
them.
I do this all the time in my house.
When you have those days when you're on like seven straight hours of zooms, etc.
You can get out of 20 seconds.
I run to my garage, which is over there.
I hop on the air bike and I will just smash out 30 seconds
as fast as I can and then walk right back in.
Love it.
Yeah.
I'm going to start.
Yeah, just also, you can just put one of those things
which I do also just put one in your office
and hop over out of there.
The whole entire thing now literally takes 23 seconds.
Before we begin, I'd like to emphasize that this podcast
is separate from my teaching
and research roles at Stanford.
It is also separate from Dr. Andy Galpins teaching and research roles at Cal State Fullerton.
It is, however, part of our desire and effort to bring zero cost to consumer information
about science and science-related tools to the general public.
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So tell me about endurance.
What is endurance? How do I get more endurance?
And how does it work?
When we think about endurance,
I would like to open up the conversation
to include more things
than people generally do
when they hear the word endurance.
So if we just think about what you typically ask your body
to do, or like to ask your body to do,
and we just walk through them,
it's going to be things like this. Number one, I want to have just walk through them. It's gonna be things like this.
Number one, I wanna have energy throughout the day.
That's actually a form of endurance.
Great, I don't wanna have these lulls and fatigue
and I wanna feel fantastic as I move throughout
my activities of daily living, whatever those may be.
Work, exercise, enjoyment,
paying attention, focus, all that stuff.
Great, that's one thing.
Another thing you
want to ask your body to do is I want to be able to repeat some small effort in a muscle group
and not, and feel great about that. This is what we generally call muscular endurance. So this is
something like, I want to be able to walk up those 10 flights of steps and my quads aren't burning
at the end of it, right? Or it's even gives me energy. Another thing you'll wanna ask your body to do
is to be able to perform a tremendous amount of work
for a longer period of time, something in the realm of,
28 to 80 seconds.
So this could be something like if you're surfing
and you've got a paddle extremely hard
for a minute to get on top of a wave.
Or you're out riding your bike
and you need to be able to get up a hill
and it's a very steep hill.
These are going to take maximal efforts for some small amount of time and then you'll
get back up there.
We tend to call that maximum anaerobic capacity.
So that the max amount of work you can perform at a high rate for some amount of seconds
like maybe a minute.
Past that is your ability to repeat an effort kind of like that for something
like five to fifteen minutes. And this is the example would be run a mile, right? Some
interval like that, which is a longer distance, right? That is going to be your maximum aerobic
capacity. Okay. Another thing you're going to want your body to do is we call sustain position.
So this is you want to be able to sit in your chair at work
and have perfect posture for 20, 30, 40 minutes, right?
You wanna be able to stand in line at a grocery store
for 15 minutes and not have a breakdown in posture.
So you wanna be able to maintain position
when you're riding your bike, you're not collapsing,
you're doing any of these activities
and you don't get hurt or lose efficiency
simply because you couldn't sustain basic positions.
All right, whatever those shapes and positions need to be.
And then the last one is a maximum distance.
So you want to be able to go for a longer hike or have just a long day at Disneyland for
whatever it needs to be and feel great at the end of it.
So the goal with all of these things is not can you just do them, but can you do them
and then you feel good afterwards.
So we're back in a right position where they give you energy, you feel good about it
and it's not just something you had to do and you're regretted and you felt awful.
So those are the factors I think about when someone says I want better endurance is I
want to walk backwards is okay, when you say endurance, what do you mean?
And that's generally the things I've come across is if you can handle all of those things, you're going to feel like you're in fantastic
shape. You're going to feel your recovery is going to be excellent and your physical performance in
the gym or any of the sporting activities you do will be enhanced. Given what you told us a little
bit earlier, that endurance really reflects fatigue and management and energy production,
endurance really reflects fatigue and management and energy production. How do each and both of those things relate to endurance at a mechanistic level?
So really what I'm asking is what is fatigue management and what is energy production?
In order to do that, it's important that we understand all of those functional capacities
that I just talked about.
They all have different points of failure.
So in order to then work backwards and say,
well, how do I optimize my performance
and all those categories?
We need to go through each one and figure out,
well, where am I failing?
Some of them are going to be failing
because of fatigue management.
And some of them will be failing
because of energy production issues.
So if we walk through a little bit
of how we make energy and how we handle fatigue, then we're gonna have a better
Understanding of exactly what to do for each one of these categories if you feel like one of them in particular is
Worse for you are lagging behind or if in general you just want to improve all of them. All right now
I'm gonna make a little bit of a 90 degree turn here. I'm gonna do a strategy, though
I promise and I want to ask you a very simple question
How do you lose weight?
I was taught that the calories in,
calories out, thermodynamics of energy utilization
governs most everything.
That is, if I'm ingesting less coloric energy
than I burn, then I'm going to lose weight.
And if I'm ingesting exactly as much as I burn,
I'll maintain weight and if I ingest more,
then I burn, then I'll gain weight.
Sure, that is the approach you would take.
What I'm asking really is how are you
actually physically losing the weight?
So my understanding is that we have different
fuel sources in the body, glycogen,
which is stored in muscle and liver, body fat, which is stored in mainly white adipose tissue,
which is subcutaneous in around our organs, intravissural fat, and that we can also use
protein as a fuel.
And then, as I recall, there's also a phosphocryotene system.
And I think you're going to tell me that each of these
systems is tapped into on different time scales and perhaps according to different levels of exertion.
And I'm certain that what I just said is not exhaustive, but hopefully it is most or entirely correct.
Pretty correct. What's I got to do with fat loss?
At some point, body fat stores, adipose sites, fat cells,
are going to start liberating fat as a fuel source.
And the stimulus for that I'm assuming is going to be that
other fuel sources are either depleted or that the
energy and metabolic systems of the body, I don't want to say
decide because they don't have their own consciousness, right? Are our, are, are
flipped signals? It's our signaling in a way that registers that body fat would be the
optimal fuel source given how long or intent and or intensely a given activity has been
performed.
Okay, we have some stuff to clean up there,
but we're still not really answering the question.
How am I actually losing that body fat?
How is it actually leaving the body?
Correct.
My understanding is that it leaves the body
through respiration.
Uh-huh.
So now we have some interesting things to talk about.
How am I actually losing fat via respiration?
What the hell is that even me?
How is something that occupied this physical space on the side of me, leaving my body through
my mouth?
And there's a very clear answer there, which I'm sure you're cute up to.
When you take a breath in, you're generally breathing in oxygen, O2.
There's some other things, but we'll just stick to oxygen.
When you exhale, you're breathing, O2. There's some other things, but we'll just stick to oxygen. When you exhale,
you're breathing out CO2. The difference between those two is that carbon molecule. Well, one of the
things that's important to understand here is all of your carbohydrates, which is that word itself,
is a carbon that has been hydrated. So it is a carbon molecule attached to a water molecule.
It is a simple chain of carbons. Your fat molecules are also chains of carbon.
All of metabolism really, in terms of energy production,
is simply trying to figure out a way
to break those carbon bonds.
As a result, we get energy from that.
We use that energy to create a molecule called ATP,
which is the central source of energy
for any leaving being, right?
That carbon is then floating around in a free form, which is bad news internally.
So we've got to figure out a way to get that carbon out of our system.
So all of energy production, all of fatigue management really comes down to this core
issue of how are we handling carbon and how are we moving it around the body?
And so what we do is we do this sneaky thing.
So another question I'd like to ask people is why do we breathe? Well, for two reasons, to bring oxygen into the system,
into offload carbon dioxide, but the neural trigger for breathing is when carbon dioxide hits
a threshold level and the set of neurons in the brain stem and elsewhere, activate the
front end nerve or the gas reflex or a combination of things and we inhale or
inhale. Right. So a reduction of oxygen intake generally doesn't stimulate
ventilation unless you're at altitude. Then that's sort of changes, right? In
general, it's an elevation in CO2 that's going to stimulate breathing out. The
only reason you bring in O2 for the most part is to get rid of the CO2.
Oxygen is not a fuel source.
It works the same with fire, by the way.
So you know you have to have oxygen present for a fire
to go and if you squelch oxygen, the fire will go out, right?
That's sort of half of how those fire extinguishers work.
But we think then that means oxygen is the fuel.
It is not the fuel.
It is something entirely different.
It is a necessary product that is necessary
for the metabolism process to actually occur.
All right, so we're kind of dancing around an idea here,
which is this carbon cycle of life.
So what happens in plants is they generally will breathe
in the opposite and breathe out
the opposite of humans.
So a plant will breathe in CO2 and exhale O2.
This is why we have to have a certain amount of these things, analogy and forests and trees
and stuff to maintain this O2 CO2 balance in our atmosphere.
We do the opposite.
So we have this wonderful circle of life.
We breathe in O2, breathe out CO2, they do the opposite.
Well, what happens is, because carbohydrates are long chains
of carbon and fats are as well.
Generally, when we think about fats, by the way,
it's important to understand that structure a little bit.
So if we think about triglycerides,
it is a three carbon backbone chain of glycerol,
so it's one, two, three.
And horizontally running off of each one of those
are fatty acid chains, right?
And so we form this structure that looks like an E,
like the letter E, three in the back,
and then three chains coming off of it.
Each of those chains are called fatty acids,
and each of those fatty acids are a length of carbon,
or a number of carbon strung together.
However many carbons are there,
determines which type of fatty acid it is, right?
So steric acid, linoleic acid,
like any different number of things.
It's also what determines whether or not
is a mono unsaturated or polyunsaturated,
is if carbon requires a special thing called a double bond.
So if there's a double bond across every carbon
and carbon, then they're all fully saturated and you're great.
If there's any of them that are not double bonded,
and in fact, an example, if there is one that doesn't have a double bond, that is now called mono and saturated. If
there are many, it is called polyunsaturated. So there's pros and cons to all these things.
Right. In either case, we're still talking long carbon chains. So what a plant will do
is bring in carbon. And then it has this wonderful ability to use energy from the sun called photosynthesis.
And it can take those carbons that it inhales and use the energy from the sun to form a bond.
Now in our prior discussion, when we were going over hypertrophy, we talked about the energy
which is required to go through protein synthesis. That's because forming a new atom, or a new
bond between atoms oftentimes takes energy in this case it does.
The same thing happens here. So if a plant does not have oxygen or does not have carbon dioxide in
the air, it has no fuel. The basic thing about it is that's what it eats. It needs to get nitrogen
from the ground in the soil. It's like we need to get nitrogen from our protein, but fuel lies
in need to get carbon dioxide. Then it needs sun to give it energy so it can actually form that bond.
That's what it's getting its fuel from.
If we think about a classic plant that produces either a starch or a fruit, here's what happens.
It inhales that carbon and it starts packing it away.
Now in a root vegetable, what it does is it stores those things together.
And if we store that thing and we grow fruit at the bottom of it,
we tend to call those things starches.
All right.
It's going to then take the carbon that is packed away in its root
and send it up the tree.
And it's going to actually do that by breaking it down into a smaller form
of carbohydrate that we tend to often call things like sucrose and glucose.
It'll ship that up the tree, it'll go out to the leaves, and it'll convert it into the fruit,
and it's going to eventually transform that stuff into smaller carbon, things called fructose.
And if we think about the fruit or the sugar in fruit, it's often in the form of fructose
or sucrose or accommodation in sometimes glucose. So we have these smaller carbon, six carbon chains,
generally in the form of glucose,
that are being made from this larger storage
of carbohydrates that we call starch, right?
So it's packed in together.
Your body does the exact same thing.
So if it's a potato and it has a whole bunch of glucose packed away, we call that starch.
If it's in your quadricep and we pack about a whole bunch of glucose away, we now call
it glycogen.
If it's in your blood as that six carbon chain, we call it glucose.
If it's in the tree and in the fruit, we call it fructose.
Those are different molecules, but that's effectively the same thing happens.
So the biology, the chemistry is almost identical.
It just runs in the reverse order.
And that's why, again, tubers and potatoes and stuff tend to be starches and fruits tend
to be glucose, fructose and sucrose.
So we have this wonderful circle of a lie.
The plants can survive on just breathing
in the CO2 and then getting the energy from the sun. We don't have that ability, at least to my
knowledge, to run through photosynthesis. So the only way we can get carbon into our system
is to actually ingest carbon, which means we have to eat the starch, the fruit, the animal, some other form of stored
carbon to get that indoor system.
We then pack that away.
We put the carbohydrates, as you mentioned earlier, either on our liver, our blood, or
in our muscles.
We put the fat generally in adipose tissue.
We'll put a little bit in muscle cells, it's in for muscular triglycerides, and then
the protein will use as structure,
right?
We'll do different things.
We don't like to use protein as material or fuel.
It's better use of structure.
And what we have to do then is if all of a sudden we realize that storage is getting too
much in our body, in other words, we're gaining too much weight, we have to figure out how
to get the carbons out of our body.
And that is metabolism, right? Any Anytime we're trying to break a carbon
bonds that we can get energy to make ATP, that's going to release the carbon out of our tissue
and the blood. We have to bring in oxygen to bind that carbon molecule to make CO2 so we can
exhale it and put it back into the atmosphere. It's a beautiful description of the circle of life and energy utilization in the human body.
I have to ask the question that I'm sure many people are wondering about, which is if indeed we
exhale these carbons and as it relates to fat loss, that is the way that we lose fat if we're in a subchloric state, for instance. Has it ever been explored as to whether increasing the duration or intensity of
exhales can accelerate fat loss? I mean, that's sort of the logical extension
of what you described. And here, I'm actually interested equally in whether
not the answer is yes, as well as whether it could be no.
Because I could imagine if the answer is yes,
well, then there's some interesting protocols
to emerge from that, but that if it's no,
it will reveal to us some important bottlenecks
about metabolism and energy utilization.
You've ever seen those magicians who like show up
and they can tell your mom's name or something like that before you because they can sort
of think you down a path.
Yeah, I mean, not to take us down a deep dive tangent, but I once went to the magic castle
in Los Angeles.
And I was one of the people called up front and an incredible magician, a named, I think
his name was Ozzy Minder, something.
I think that's right.
Had me write my name on a card in a Sharpie pen.
I ripped up the card.
I ripped it up.
I put it in my pocket.
And at the end of the 10 or 15 minute bow
of him doing a bunch of other tricks,
he asked me to look in my right shoe
and under my foot in my right shoe was that card intact.
Yeah.
And it was no longer in my pocket.
And I swear my life, I wasn't a collaborator with it.
And to this day, it still gives me chills
because it bought, I don't know how I'd magic.
Yeah.
Right, magic.
Well, the reason I say that is,
I've given that little spiel
that I just gave you that countless times in my classes.
And I would say 99% of the time,
as soon as I stop, the very first question is,
so can I just like do a bunch of exhales and lose fat,
which is wonderful,
because I was really hoping you would do that,
and you rolled right into my trap.
You landed perfectly, so I look like a magician over here.
I feel like I should look in my right shoe right now.
No, I asked the question because it's the logical extension of what you laid out, but I
know biology to be both diabolical and cryptic, but also exquisite in the way that things
are arranged and you don't get something for nothing.
There are no free passes in physiology.
That's the saying, no free passes.
The answer to your question is yes.
A lot of 100%.
Yes.
In fact, that is the only way to go about it.
You have two options.
You can ingest less carbon or you can expel more carbon.
People always say calories in, calories out.
It's really carbon and carbon on.
That's what a calorie is, right?
Calories and amount of energy we get per breaking carbon bond. So it's really less in, less more
out, less in is fairly obvious, whether that comes in any form. And by the way, this is
exactly why the percentage of your intake coming from fans or carbohydrates such, it doesn't
really matter that much. If you look at fat loss, clinical trials, you guys may have covered this.
When Lane was in here, I'm sure,
like this is something he talks about a lot,
it doesn't matter.
It's irrelevant because it's not about that.
There's nothing magic in those things.
They are different.
They have different physiological responses.
Everything is different, right?
No, no.
But in general, it's just simply about carbon intake.
Turns out fat has a lot more carbons,
per mole, than carbohydrates do.
So there's more calories per mole in there.
So if you, the physical amount of fat needs to come in as
a smaller amount, physical amount of carbohydrates,
it needs to come in as a larger amount.
But you can play any number of very high carb, low fat,
what matters, total calories, right?
Again, it's not like the only thing that matters, but you know what I'm saying?
Some percentages in the way can go fat loss works fantastic, high fat low carbohydrate.
Why?
Why are all these things work?
Because that's not about that.
It's about total intake of carbon, total expo.
So absolutely, can you lose fat by simply exhaling more? In fact, that is exactly
what you did this morning. When I hopped on the airdine bike for more than anything, right?
The question is, can you think of a scenario in which you could have a bunch of increased
rates of exhalation that helps in fallows? Sure. I think of a lot of things that will stimulate
increased rates of exhalation. One thing could be simply going, right? So the question is, like,
can I literally do some breath protocols where I force exhale and lose fat? And the answer
is yes. But what happens? What happens if you do hyperventilation training? Well, my
lab studies cyclic hyperventilation is one of our many deliberate protocols.
And one of the most prominent things that one observes is that levels of adrenaline
increase very quickly.
Extremely quickly.
People feel jittery, anxious, stressed, and unless they are consciously trying to anchor,
they're thinking about what that means and the benefits that to persisting.
Typically, they abort the
cycler hyperventilation protocol really quickly. Within seconds. You will feel tingling, sweating,
all kinds of things. You're hyperventilating, right? And we could talk a nauseam about how that
changes everything from adrenaline to focus the whole bunch of things. So, unfortunately,
a strategy of sitting around just exhaling more than you inhale.
Technically helps you lose more fat, but it's not going to last very long.
So then the question is, well, how do I get into a situation or a scenario in which I can increase my rate of
expiration where I'm not going to pass out. I'm not going an altering hypokapnea and hypercapnea issues.
Any idea of a situation in which you would have an enhanced
rate of explanation without worrying about passing out?
True, steady state exercise.
Or not steady state exercise, lifting weights, intervals,
moderate training, repeated, any of these things.
They all work equally for fat loss
because all they're doing is increasing respiration rate.
They're saying increased demand
for energy, increased exhalation. That's the trick here. And when you equate these things
to that, they have equal success in fat loss. It doesn't matter theoretically where you're
getting it from. And so when we get into this idea of, well, what are the best training strategies for fat loss? It doesn't matter which one of these tactics you pick as long as you maintain
a consistent adherence over time. Because of this exact fact, it doesn't matter if you're
burning, quote, unquote, fat in the exercise session, or if you're burning carbohydrates in the exercise session, it is totally irrelevant
to your net fat loss over time.
Okay, now there's some significant misconceptions there
about what I just talked, and I would love to come back
and walk through that in more detail,
but that's the main take home message here.
It won't matter what's coming in,
and it won't matter what's coming out,
because in either case, it is the same rate of oxygen in and CO2 out.
That's the key metric.
And hopefully this helps a lot of people have some relief because they're like, man, you're
so tied up on what is the exact protocol for training for optimizing fat loss.
What's the exact nutritional intervention I need for fat loss?
And then you wonder why all these different diets
can work effectively.
And wonder why all these different training protocols,
and surely you know somebody who lost a bunch of weight
and the only thing they did is they just started running.
There was no advanced protocol, they just started running
and they ran five miles every day.
That works.
And then tons of people who tried that
and like didn't lose anything.
And lots of people who went to,
I went to cardio kickboxing class, lost weight.
Oh, I just started doing intervals on my,
why, why?
Mysteriously, you'll do all these things work.
They're, you have,
something has some spidey sense
has to be going off in your brain.
We're like, there has to be something linking these things.
And what's linking it is simply carbon exchange.
So put yourself in a position
in which you are exhaling more than you and inhaling without passing out. The other problem is if you were to simply
do a breathing protocol, while the rate of exhalation would go up, after that you would correct
and go in the opposite direction. So that's the problem is your net carbon output over
the course of the day is not going to change unless you increase the demand for energy.
And that's how you get into that negative state.
Along these lines of exhaling carbons
as the route for fat loss,
it makes me wonder whether or not
increasing lung capacity is possible.
I'm guessing the answer is yes.
And whether or not increasing lung capacity
is a good goal in route to enhancing fat loss. Essentially
what I'm asking is if you can offload more CO2, okay, carbons per exhale, are you a more
efficient fat loss machine? It's a wonderful thought and the answer would be
not, not something to worry about because if you were to exhale more carbon than
actually needed, now we're in a state of inefficiency. You're burning way more energy than needed
to do your activity. The heart has a metric called cardiac output. This is in science.
We abbreviate this as Q for some odd reasons. It's either CO or Q. And cardiac output is heart rate multiplied by stroke volume.
So it's how many beats per minute you're having as well
as how much blood's coming out of it.
So cardiac output is actually very specific to energy needs.
If you try to work around that,
it's just going to adjust itself.
So what I mean by this is,
if you were able to increase your stroke volumes,
the amount of blood coming out per pump,
you would automatically adjust to reduce your heart rate
so that you keep cardiac output
exact to energetic demands.
So you're sort of pushing one in the spectrum,
but your body will pull the other one back
to keep you at that exact same neutral level.
So if you look at, if you think about like
cardiovascular adaptations to endurance training
and any type of endurance training.
A common thing people will understand is resting heart rate. And so what that number is,
is just how many beats per minute you're having when you're sitting here doing nothing.
A very positive adaptation is a lowering of that resting rate over time. As general numbers,
what you will hear is people will say things like a normal resting heart rate is between 60
to 80 beats per minute.
And if any of the things I've talked about with the individuals I work with, I don't work
with anybody with disease, just to clarify that.
I don't do anything with disease management treatment, anything.
It's always about people who are in a good spot, who want to optimize or get to the next
level, whether this is professional athletes trying to peak
for physical performance or the folks
in our rapid health optimization program that feel good,
again, it's not disease stuff,
and they want to feel incredible.
One of the metrics we're going to pay attention
to is this resting heart rate.
So here's what happens as you improve your endurance.
Your resting heart rate will go down.
If I see somebody over 70
beats per minute, unless something's going on, you're not physically fit. Regardless
of whether or not that is quote unquote within the normative values, I want to see
everybody some 60 beats per minute or close, right? That's not a difficult thing
to really get to for most people. So if you train a lot, regardless of how you
train intervals, steady state, it doesn't
matter, that resting heart rate will come down.
But since energy demands at rest haven't really changed, cardiac alpha stays the same.
So what happens is stroke volume goes up.
So literally like we train your quadriceps on the legist ends of machine, to get stronger.
So you can produce more force per contraction.
The heart will do the exact same thing.
And so as you're able to get more of the blood out of your heart per pump, the heart realizes
I don't need to pump as often.
So that's the compensatory adaptation, which is saying, hey, look, I don't need to beat
60 times a minute.
I now need to beat 55 times a minute because I'm getting the same amount of blood out
per pump, chill.
And this is why your resting heart rate goes down,
your resting stroke volume goes up,
but your cardiac output is identical.
So that's not a good metric of fitness.
It's going to stay the same.
Cardiac output will only adjust
per energetic changes.
Energy requirements in a acute moment, right?
How much do I need?
Go, which is going to be determined by ventilation, right? How much do I need? Go, which is going to be
determined by ventilation, right? How much air am I bringing in and putting out? That's going to
determine cardiac output and that's going to determine where we're at. If you were to do like a
sub-maximal exercise test, when you were unfit to when you're fit or when you're fit to where you're
super fit, at sub-maxima, you're going to see the same thing. Cardiac output will be identical and you're like, damn, nothing happened. What you're not
realizing is your heart rate at that same workload is now lower. And that's efficiency because your
stroke volume is higher. Where it gets people tripped up is that max? Because you may not
see a much of a change at max because you don't really see an increase in maximum heart rate with fitness, that's not a thing.
So maximum heart rate is not a good proxy for fit or unfit, like that.
Stroke volume will get limited eventually by filling capacity of your heart.
It has to have so much time to fill up with blood before it can contract again and squeeze
the blood out.
And when you have a heart rate of 200 beats per minute, that just doesn't leave much time
to fill.
And so it won't really push you past that.
So don't worry about trying to increase your maximal heart rate.
That's not necessarily a good thing and it won't really change.
But your cardiac output will, because stroke volume will be higher.
But that doesn't necessarily mean that I should avoid training that gets me up toward
maximal heart rate, correct?
Oh, you should absolutely do it.
Right.
That's what that was my assumption.
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huberman to claim the special offer. Getting back to energy production and metabolism.
So we've got these different modes of moving energy, but making and breaking energy bonds in the body, moving
energy into different tissues and out of different tissues and indeed out of the body through
exhalation. How do each of these different modes of energy utilization relate to different
modes of movement and exercise? In my mind, I'm starting to draw a bridge between, okay, when I walk for 60 minutes,
you know, if I'm talking, I'm breathing a bit more,
maybe I'm burning a little more fat.
After all, speech is a modified exhale.
And if I'm sprinting, breathing differently,
and if I'm, you know, doing a 30-minute moderate, quote-unquote, moderate jog, breathing differently. And if I'm doing a 30-minute moderate, quote unquote, moderate jog, breathing differently. So
you've beautifully illustrated this bridge between energy
production and utilization and carbon dioxide offload through
exhalation. What are some of the specifics about energy
utilization according to different modes of exercise? And if we
could better define modes of exercise
or types of exercise that trigger specific adaptations,
I think this is where the bridge will move
from being a mirror line to a real structure.
Yeah, absolutely.
I wanna lay one more foundational piece.
And then it's going to be much easier to understand
the limitations I put on some of these training protocols
as well as the lack of limitations.
Okay, so it's really, really important.
The way I want to start this is,
we have this foundation now of carbon
and basic energy production.
That's not to say there's no difference.
There is, and that difference is important.
But maybe we can answer the question from earlier,
which is, is actually something you
asked me this morning when we were exercising. You're like training fasted, right? Does training
fasted enhance fat loss? And the logic is sound. If I don't have any fuel, then I should be burning
more fat. Therefore, I should be losing more fat. It's not true.
It's a great idea. It's one of these classic things in science
and exercise physics.
Physiology where it sounds good, turns out it's not.
It's actually a pretty gross misunderstanding
of metabolism.
So it's not the pick on that topic.
I don't really care about that topic,
but it is a common question.
It also gives me an opportunity to just tell you
more about metabolism.
So here's what happens.
You are breathing in O2 and breathing out CO2.
However, the ratio to that is what we call the either RER,
respiratory exchange ratio or RQ, respiratory quotient.
And I'm not going to differentiate those two.
They're not the same thing, but we're going to skip past that for now.
As you begin to increase exercise intensity,
the percentage of O2 to CO2 rises in the favor of CO2.
So you start breathing out way more CO2
than you are breathing in O2.
And so if we were to look at that number,
you know, what's the relationship,
it goes up. So at rest, most people have
a of a value that we would typically call
something like 0.6.
Okay. And that's again, the between 0,2 and 0,2.
Maybe 0.7. If you were to go for a walk, that increases slightly,
because you're now expiring 0,2 at a higher rate.
So now you've moved up to say 0.8 or something like that.
One of the ways that we mark somebody
of achieving an actual VO2 max on a test
is if that value exceeds 1.1.
Now, any of you who are paying attention are thinking, well, wait a minute, how the hell can
a ratio between two things ever get passed one? Well, that's because you're getting into place where
you're actually offloading more CO2 than is actually necessary. And this is what actually causes and
explains a thing that people like to call E-Poc,
which is excess, exercise, post-oxygen consumption.
This is another way to think about it.
The only reason you're breathing
is to bring in oxygen when I'm floating CO2, right?
If I'm no longer exercising, why am I still breathing?
In other words, once you stop the demand
or the need for energy,
you should stop ventilating, but you don't.
That's because in the case of low intensity exercise,
the second you stop,
you're right back down to resping ventilation.
No problem, because you were able to match the need
for energy with the offload of waste
one to one during that exercise.
When you start creeping up the intensity, you can't do that.
So you have to basically start stealing a little bit of fuel here.
So even though you're done exercising, you're still ventilating because you have to pay
that back.
And pay that back by that, I specifically mean you have to bring in oxygen, because you
have a whole bunch of waste that's been accumulating in your tissue that you've got to deal with.
And I'll walk you through what that waste is.
It's a particular molecule that a lot of people have heard of, but grossly misunderstand.
So you've got to be able to handle that.
So the reason that you sit there and go, and continue to ventilate is because you're
now trying to pay back that excess post exercise oxygen debt.
That's that oxygen debt we're specifically talking about.
All right.
So, that being said, as we start cruising up that RQ starts going up, up, up, up, up,
up, up, up, up, up, up, up, up, up, up, up, up, up, up, up, up, up, up, up, up,
and if we get the one year, one point all year, you're in a, like you're hurting, you're
in a, you're in a pretty good spot.
All right.
I like it.
You're hurting.
You're in a pretty good spot.
Yeah.
Is a window into Dr. Andy Galp, whose mind.
Yeah.
Now you really want to be a subject in his laboratory studies.
Sure.
Massacus is warm to Andy's lab.
Absolutely.
All right.
So, the idea that I will lose more fat by being in an exercise situation that is burning
more fat by being in an exercise situation that is burning more fat.
It seems to make sense, but it's a massive failure to understand the metabolism.
It's the exact same explanation to why exercising fasted doesn't matter.
So the exercising fasted issue on a normal circumstances is irrelevant because you have plenty of
fuel in the system, even when you you haven't eaten breakfast that morning. Now, if you're talking like extended fasting over multiple days, this is a different scenario.
If muscle glycogen, liver glycogen, and blood glucose are at sufficient levels,
then you absolutely have enough energy to perform almost any type of exercise that most people
are doing. Maybe if you're Rob and you're at mile 20 today, it's a different story,
but the vast majority of us have plenty of fuel sitting around, so we're not going to burn
more into fat just because we didn't eat breakfast that morning. So that just doesn't
make energetic sense. We have a lot of backup supplies you're never out. The trick here
is this, there's a concept here we call crossover concept. So as we are starting to move up
exercise intensity, we start burning a higher percentage
of our fuel from carbohydrates and a lower percentage of our fuel coming from fat.
I'm sleeping.
That's the highest percentage of your fuel that will be coming from fat of any activity
you could ever do.
So, if the theory that I'm going to stay at a lower intensity to burn more fat was true, the
optimal fat burning strategy would then be to sleep.
That doesn't make sense.
Of course it doesn't.
Why would then go ahead and slightly elevate it to rate?
Somehow all of a sudden, magically make you lose fat.
It doesn't actually make sense.
When you think about that, we were like, oh, yeah, there's no way.
It's a percentage trick.
It's a difference between absolute and relative.
This is what this confusion is.
So yes, as you start doing lower intensity exercise,
whether you're faster than not, it's irrelevant.
But lower intensity exercise, a greater percentage
of your fuel is coming from fat.
However, your total fuel expenditure is very low.
So that whole total carbon balance
is not really being shifted much.
As you start exercising in a very high intensity,
you actually start getting a higher percentage
of your fuel from carbohydrate and a lower percentage
from fat.
In fact, at rest, about the highest you can get
in most people is about 60% of your fuel from fat. As you're sleeping,
you might be 70%. But you'll never be in a position ever, no matter what sort of thing you've
heard on the internet, you'll never be in a situation where fat is your only fuel source.
The highest I've probably ever seen is like 70%. You should probably be it about that. That's a kind of a good number to think, honestly.
But people will understand a little bit of amount of tablets and to be dangerous, but not
enough.
We'll throw out these terms like fat adapted.
And fat adapted is a real thing, but is a mass-admiss understanding oftentimes, right?
It is this idea of thinking like I can get into a spot where I'm maximizing fat burning. Maximizing fat burning and maximizing fat for exercise
and maximizing fat loss over time
are not the same thing at all, right?
That's the confusion.
So if you enhance fat oxidation and exercise
that does not enhance fat loss per se, right?
So this is a lot of the confusion that's happening. Right? So as we start moving up,
we can never get into position where we're using fat only as a fuel again at best year at 70% fat,
30% carbohydrate. For a lot of reasons, we probably just don't have time to get into today. However,
the opposite is possible. When you get into true high intensity exercise, you'll be basically 100% carbohydrate and 0% fat.
That is very possible.
That in fact is 1.0, that's not our cue.
1.1 is actually, because your ventilation
got so high, you've actually exceeded that number,
even though you're at 100% carbohydrate.
This is what people came up with the idea then,
it's like, well, I don't want to burn carbs,
I want to lose fat.
So my response to that is always like, okay, great. So it makes
sense burning fat, losing fat, burning carbs is losing what then? Like do you think you're liver
shrunk? Like, wait a minute, what did you lose then? Where did it come from? It's all coming as
carbon. Don't worry about where it came from for your fuel. It just has to come out as carbon.
There are differences in exercise efficiency
for performance with our professional athletes, of course. But if the only goal here is fat
laws, it doesn't matter where you get it from. The last bridge we have to connect here is like,
well, wait a minute, if I only burned carbohydrate, how did I actually lose that fat? There was that
there was that love handle sitting on the side of me. How did that come out of me?
If I never burned that from my fuel.
What you're failing to understand
is there's a balanced game that happens here.
So if you were to do a bunch of high intensity
exercise training and you burned only muscle glycogen
and blood glucose and maybe even you did it
for so long, you burn some liver glycogen.
The body understands that it has expelled a lot of energy from that side of the equation.
It's going to do a couple of things.
Now, it's very difficult to go through this fancy situation where you convert carbohydrates
into fat and back and forth.
That's actually fairly hard.
What's easier to do with something you said earlier is actually just bias energetics
to a different fuel source. So in that scenario, where you're down really low
in your carbohydrate stores,
any carbohydrates you bring in are going to go to storage.
And since your net energy expenditure is something
that your body regulates a lot,
any fat that you then bring in is going to be utilized
as a fuel source because it knows it doesn't need it anymore. That is in excess. So that's how you actually use fat as a fuel
because you've burned down carbohydrate storage. As I'm hearing this, a couple of things
come to my first of all. Thank you for that incredibly important description of what is otherwise
a very confusing landscape for most people. One of what is otherwise a very
confusing landscape for most people. One of the key points I took away and
I just want to say from the outset this is not exhaustive by any stretch is that
burning fat does not equal losing fat from the body. Correct. And then burning fat has to be divided into burning of body fat stores and we need to distinguish that from
burning of dietary fat that is brought in.
Oftentimes people don't disambiguate those.
Correct.
And I'm also understanding that reducing one's body carbohydrates stores, muscle glycogen,
liver glycogen, etc.
Occurs during high intensity exercise.
Yep.
Those are the ways, but that is one very efficient way
to tap into those stores, which makes me wonder,
again, this is one of these things that does it lead
to a protocol, makes me wonder whether or not
doing high-intensity, let's say weight training
for 45 to 60 minutes, 75 minutes of strength training,
power training, hypertrophy training,
which we've covered in an episode about those topics.
And then doing some steady state cardiovascular exercise, is there any benefit to that arrangement
that would, quote unquote, enhance body fat loss from the body, to be very specific now,
because unlike the idea that training fasted would shift the bias towards fat loss,
which it doesn't, you've told us,
under those conditions, muscle glycogen
and maybe even liver glycogen is going to be depleted.
Put simply, can I enhance body fat loss
by doing some cardio after a bout of weight training?
If you equate for total energy expenditure, it won't matter.
Now, you did bring up a very important point that I want to clarify.
If you look at the exercise modalities that we laid out in our previous conversations,
we talked about nine different adaptations.
One was skill and then speed, power, strength, hypertrophy, muscular endurance, anaerobic
capacity, aerobic capacity, and long duration endurance.
Now, speed, power, and skill development have almost no benefit for fallos because remember
those are low weight, a lot of rest, and low volume.
They're not really really going to be helpful.
You can make a little bit of a case for strength,
a little bit, but the total energy expenditure
for strength training, even if it's an hour,
if it's truly strength training, it's fairly low.
Because the repetitions are in the one to three range.
That's exactly, it's not enough for total work.
So if you're trying to develop a protocol
that sort of optimizes fat loss,
what you want to do, you're close. And my opinion is do a combination of something in the hypertrophy
slash muscular endurance strength training realm. Okay. So six to 30 repetitions, something like
that resistance training, deplete muscle glycogen, maybe even a bit of liver glycogen.
Maybe a little bit depending on if you're doing it for a long time, but probably not a noticeable
amount.
Okay, so an hour of hypertrophy type training.
If you're training hard with low rest intervals and you really did an hour, you would for sure
get there, but most people don't.
Because you're taking a lot of risk.
Because you're taking a lot of crazy, large bulls of oatmeal and rice after I do weight
training.
You want to replenish muscle glycogen.
Totally, right?
Then you may be do a little bit of very high intensity, maximum heart rate, well overvealed to max.
A hard as you can for 20, 30, 40, 5, 60 seconds,
something like that with some recovery,
a lot of recovery and repeated.
And that's going to do a great job
of replenishing muscle glycogen, right?
And if you do that long enough,
you'll get the liver, but again,
most people don't, because it's really, really hard
to go that hard.
So liver is sort of last resort?
Yeah, basic mechanics here,
which we'll actually get into as our like third segment here
is energy production comes from the local exercising muscle,
first and foremost, from phosphocretin and carbohydrates stores
Right and again, and we store it in a muscle we call it glycogen
Right, that's it's your first sign at light on defense if you need
glucose outside of that you're gonna start pulling it from the blood
But one of the things your body regulates a handful of things over almost everything blood pH blood glucose blood pressure and
Electrolite concentrations like it really does not want to mess with those things at all. It will change almost anything
else in the body to keep those things standardized. Generally, because you need all those things
for your brain to work, and your brain will stop working. If you lose blood pressure,
it won't go up there. pH changes, you can't run metabolism, electrolytes change, you can't think.
And glucose is a primary fuel source for the brain. It's going to be a problem,
right? So if that number starts to come down because you're grabbing glucose out of the blood,
your liver is going to then kick in. It's going to break down. It's glycogen to put glucose
into the blood to keep the blood number the level. In fact, one of the things you'll see is blood
glucose concentrations rise during exercise. They don't fall. In fact, they rise as an
anticipatory state. If you train a lot, your blood crystals
start going up before you start moving. It knows it's coming,
right? So you, you can play that game. You can rob Peter to pay
Paul for a long time and tell your liver runs out. And that's
what actually is a bunk. And in terms of like long duration
endurance stuff, you're talking many, many, many, many miles
several hours, typically we say, Oh, it's got to be over two
hours. Before your liver starts to become a real problem or it has to be tremendously intense because of
those reasons. You have to burn through just a lot of energy before your liver
starts to get into a problem. You can continue to train when your muscle glycogen
levels are low. In fact, people say glycogen to patient and muscle but it's
it's generally misnomer and you are going to just have tremendous signals of
fatigue when that number gets lower than 75%. So people think that like their and muscle, but it's generally misnomer. And you are going to just have tremendous signals of fatigue
when that number gets lower than 75%.
So people think that like their muscles
are getting heavy, you're probably still 75% full.
A lot of folks will quit around the 50%.
The highest I've ever seen is like 95% true to completion.
And that's in extremely high level cross-country skiers
and like their deltoid gets very, very low.
Some very talented runners will get fairly low
in their quads, but the vast majority of folks,
by the time you're 50% depleted, you're gonna quit.
It's going to be really, really challenging.
So you're never really going to get that low.
It's like a bit of a protective mechanism, right?
But when your liver gets low, you're gonna be shut down.
And that's the case with everybody like a marathon
and you've seen people run like 25 and a half miles and then they just like bonk. They go into like baby deer walking, stands and then they collapse and you're like,
how are you mentally weak? Like you ran 26 miles and you can't run the last point.
And a mentally weak, it is, if your liver is done, it's going to stop you because there's no more backup reserves.
Muscle, you can get away with, you can push through it.
Liver will not let you go any farther.
I find this fascinating because it makes me wonder whether or not the liver being depleted
sends a neural signal to the brain.
Or the brain must register some signal.
I would like to be alive tomorrow.
Thank you.
Whatever is happening right now, stopping is going to be safer than continuing.
And so that stop signal is one that I think a lot of people,
including myself, are intrigued by,
because we always think that it's related to willpower.
But the brain needs to preserve itself.
And as the master computer,
I mean, there are ways to go into kind of automaton type,
not thinking just doing type behavior.
You have override switches, right?
And you can play those cards.
And you can get better at learning and being
being less sensitive to that switch.
That's exactly what happened when you first start training.
Right, you start to realize like, oh my gosh, I'm super tired.
And then you realize really quickly, like, oh, I'm totally fine here.
And this is like the pick your person who's made
sayings like this.
But it's like you're really only 10% depleted
or 30% or 40% or some we're all operating 40% of what we could do.
Of course.
Any of those things are true because it is like a little bit of an override.
You've just gotten very sensitive to being a small percentage depleted and you've learned
okay, I'm tired.
And there is a long way to go past that.
But once you get past that and you flip that override switch a lot, you're going to break
quickly because you basically learn to ignore that signal and problems can happen really
quickly after that.
And that's even experienced endurance athletes.
If you hit that level, it's like you're going to be hitting the concrete next.
And that's potentially a problem.
I want to make sure I understand a concept that you referred to earlier correctly because
I have a feeling that I don't and that's this issue of how the body accesses body fat
stores when in a sub-colouric state and I'm doing mainly glycogen burning exercise. Yeah. What I heard you say, and please correct me
where I'm undoubtedly wrong,
what I heard you say was that, okay,
I go into the gym and I start lifting weights.
I'm burning muscle glycogen,
mostly local to the muscles that I'm using,
and then I start pulling glycogen from the bloodstream.
Maybe there's some body fat stores that are mobilized,
probably not dipping into my liver glycogen.
Okay, I complete the workout.
Maybe I even hop on the airdine bike and do a little sprint.
Yeah, I go for a jog.
Maybe I eat immediately afterward.
Maybe I don't eat for a few hours afterwards.
But across the day, I ingest fewer calories than I burn.
Is it the case that body fat is mobilized
in order to replace the glycogen
that my sub-chloric intake was insufficient
to provide.
In other words, because I didn't eat enough
to fill the glycogen stores,
am I using body fat converted into glycogen
to fill those stores?
Right.
And if so, is that a case where I'm no longer ex-handling
carbons in order to burn body fat,
but rather I'm repurposing body fat into muscle.
Have I turned fat into muscle in that case?
Yeah, I'm really glad you asked this because I did a very poor job on that last point
talking about earlier.
I'm realizing, playing back on my head because there's so many really good questions.
You cannot turn fat into muscle.
Can you turn muscle into fat?
No.
I'm so glad you said that because when I was in college
Yeah, our I don't want it out that person the physiology teacher
seem to think still at that point that one could
Lift weights get muscular, but then it would eventually turn into body fat that I that myth as I think largely been dispeled
I heard that so many times as a kid, I heard it so many times in college. I heard it so
I hear it so many times in our undergraduate students from other faculty and such. So
no, they're not the same structures. They are very different. Let me take a shot and
answer in this better. You were really, really, really close. So, yeah.
If you were to do that type of exercise
where you've burned a lot of muscle glycogen,
how is it I'm losing stored fat?
All right, that's really the question.
And it doesn't even actually matter
if you then went ahead and ingested carbohydrates
or fat post-exercise.
That's not really the thing.
You've hit on a couple of key things.
Number one,
this is all under the assumption that total caloric intake is still low, right? You have a total need.
Below total. Okay. I also want to flag calories in, calories out is not the only thing that matters.
This is a very complex thing. Calories in is incredibly complicated. Calories out is even more complicated.
So we just, maybe another series, we can spend on that alone.
So don't go nuts about that.
You have to be hypocaloric one way or the other.
If you burn a bunch of muscle glycogen and you are hypercaloric,
you're still going to add fat.
If you burn a bunch of muscle glycogen and you're hypocaloric, you're still going to add fat. If you burn amongst a muscle glycogen and you're a hypochloric, you're going to lose fat.
Think about it this way.
You're in a negative calorie state.
Where are those calories going to come from?
Are you going to reduce your muscle glycogen storages permanently?
No.
No, are you going to reduce your glycogen storage in your liver?
No.
You want to reduce blood glucose?
No.
No way, right?
So where is that extra energy coming from?
It's coming from your storage fat.
It is your backup reserve energy system.
The way that I want to flag this here is
people tend to think about it as like carbohydrates versus fat.
That's not, it's more like a chain, more like a bicycle
where there's a front gear and a back gear.
You turn one gear, it turns the other one.
These are complementary systems.
They are not and or systems, right?
You're turning one, and when we go through carbohydrate metabolism, maybe here in a second,
you'll understand why you have to have an anaerobic and an aerobic component to that.
There is absolutely no way to complete carbohydrate metabolism without oxygen. That has to happen.
The only way to engage in fat metabolism is aerobic and oxygen. There's no anaerobic component
to it. There's a fundamental difference there. So, your carbohydrates are meant to be incredibly
flexible. It is a primary fuel source for a reason. Your fat is not meant to be flexible.
It is meant to be unlimited. That's the basic
point. So you want flexibility over here and an unlimited capacity over there. Now I'm safe
guarded against any energetic need. Okay. I need to run up a hill for safety. Cool. Carb
hydrates are there. I need to then run for 17 hours. Cool. Fat is there. We want both of
these systems. You want to be able to have great energy throughout the day.
You want a slow drip coming from fat.
You don't want up and down, up and down, up and down.
Awesome.
You want to be able to think very quickly and get hyper focused.
Boom, carbohydrates ramp right up, right?
Get it into the brain, get thinking better, get thinking clearly fast.
So we want all of these, not just for exercise purposes, but for activities of daily living,
we want an optimal system here.
And when people use the terms like fat adapted,
they're generally hijacking that.
And they're thinking, it used to be a thing
we set all the time in like all of my undergraduate classes
for years.
And that idea of metabolic flexibility
is using optimal fuel sources and optimal times,
not maximizing fat usage.
People have co-opted that term,
a metabolic flexibility to be like,
oh yeah, yeah, therefore learn how to maximize fat burning.
That's not what that term means.
That term means maximizing your ability
to use whatever fuel is optimal in that time.
Now, I'll grant you, most people aren't fantastic
at using fat as a fuel source,
relative to the other direction,
but nonetheless nonetheless the gold
standard here should be maximizing both.
Right, finally answering your question.
If I were to burn a bunch of muscle glycogen, how am I losing that fat?
Well, the fuel you're ingesting in that hypochloric state is going to say, hey, look, we have
a lot of muscle glycogen, we have to replenish.
So any carbohydrate that comes in needs to be biased towards storage.
It's got to go into those tissue. Any fat that comes in or doesn't even come in,
but any fat that we're using for fuel needs to be utilized for activity.
And that's where the caloric expenditure from fat comes in. So you're basically saying your
where the caloric expenditure from fat comes in. So you're basically saying your general physiology,
the energy for that starts coming from fat.
And the energy that's coming in from carbohydrate
needs to be simply stored.
And so what you see is your respiratory cushion changes.
All right, the RER is going off.
And so in the exercise moment,
it's shot way up for carbohydrates
and shot way down for fat.
As a compensatory response, it goes the other direction because your body is saying, we
are low on carbohydrates.
Don't use them for fuel unless we absolutely have to, right?
So use them for storage.
Get our fuel from the fat side of the equation.
And so what you're generally going to say is like, oh, I'm burning more fat just sitting around
after things like that.
And that's not even taking into the equation
the epoch part, which is like,
it's not actually as large as people think.
It is, it's fairly small.
But it adds up sort of over time.
So does that explain a little bit better
about how you lose fat when you actually only burn carbs
for exercise? You explained it beautifully. You talked about epoch, the post-exercise, oxygen consumption.
Not being that significant in terms of energy utilization. Even though today we're talking about endurance and different forms of endurance, I do have to ask whether or not people consider the
I do have to ask whether or not people consider the
elevation in basal metabolism that occurs when there's more muscle around. Yeah, because muscle is such a metabolically demanding tissue
you know if is there a straightforward ish
Equation, you know if one adds one pound of of lean muscle to their body, even if it's distributed across multiple muscle
groups, does that equate to a caloric need of X number
of calories per day?
And is that because of the muscle protein synthesis needs
of that muscle, or it's glycogen storage needs, or both?
If you don't have enough muscle,
you start to have problems with fat loss.
It's difficult challenge. If you have enough muscle, you start to have problems with fat loss. It's difficult
challenge. If you have enough muscle, and you're just trying to get extremely large, if you
fear FFMI is 24 and you're 15% body fat, adding more muscles, not really going to play a lot
in the equation. And here's why. Muscle is more metabolically active at rest than fat, but fat is not
inert. So fat is still going to burn a small number of calories.
Muscle burns more, but it's not nearly what people think it is.
I'm a muscle guy, I'm a muscle physiologist.
I would love to get people to have more muscle for any excuse I can.
It's not honest to say that though.
You're talking about when I was in undergraduate,
we would say numbers like 50, K-Couple day per pound is what you can look at, right?
So if you put on a pound of muscle spread across the body,
your basal metabolic rate would go up by around 50 calories per day.
I think that number is grossly exaggerated.
It's probably a tenth of that.
Six to 10 calories.
Maybe it's hard to know exactly what that number is,
but the more recent estimates
are something like that.
So now on one hand, you could say, oh my gosh, that is not even meaningful.
The other hand, you could say that's super meaningful.
It just depends on time domain.
You want to put that out, right?
So if you were to put on five pounds of muscle and your meso metabolic rate went up 30
or 40 calories a day, well, over the course of a thousand days, like that actually adds
up. So you could slice this anyway you want. Now, maybe that number somewhere in between,
I don't really know. It's not a field I pay that much attention to candidly because it's
not a metric kind of like epoch where it's like, we used to really harp on it. And now it's
like, well, maybe we exaggerated that, like, honestly, just a bit.
But to me, it doesn't change the equation much because if you don't have enough muscle,
as I described there, other consequences that are going to make fat loss hard.
And so you need to have sufficient muscle.
If the additional Chloric Expanditure is the carrot, great.
If it's something else, I don't really care.
There's just enough evidence that you need to have it, or I should say, there's enough
evidence that it will really help you in your path.
Maybe a few calories here there is not really that thing, especially if you understand
a normal food item.
Anything you pick is going to be probably a couple of hundred calories.
One bad food choice today, well outkick kick almost any amount of coverage you got on an
adding muscle mass to you.
So like, you're really stepping over a dollar to pick up a dime.
If you're worried about how many calories you're getting from adding muscle, fat loss is
going to be about regulating that carbon intake above and beyond anything else.
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So I've heard about this concept of metabolic flexibility
mentioned a few times.
Frankly, you're the first person
who's ever explained it to me in a clear and concise way.
How do I know if I am metabolically flexible?
And how do I increase my metabolic flexibility?
Sure, there's no specific standard, which is actually a good thing.
So if you have a level of specificity that you want or need metabolically, then you don't
actually want to be in this middle ground.
An example would be if you are a performing in a type of exercise or an athlete who performs
in a sport that is like a legally dominated. You don't want to be optimally
metabolically flexible. You don't want to be super quote unquote fat adapted. You want to be
biased towards the energy you're going to use. The same could be true for the other end of the
spectrum. So in those particular cases, it's not optimal
to be equally effective because there are no free passes in physiology. Right. Your
effective because there are no free passes in physiology. Right? Your energy producing systems will up-regulator down-regulate
accordingly. So you will actually limit your ability to say
maximally utilized carbohydrates as fuel if you're trying to up-regulate
your ability to use fat as a fuel. And so this is like, there's a saturation point.
Outside of that spectrum, most people would just say,
hey, like I want to feel great throughout the day
to be able to do a bunch of different things.
How do you know?
A couple of things.
There's a lot of biological markers you can take.
There's also just some practical takes.
Now none of these markers by themselves are any sign.
What you want to do is probably a couple of them
and then say, okay, this is maybe a clue.
So again, it's really important to emphasize
not a single one of these tests
that I'm about to walk you through.
Automatically means you can't use that as a fuel,
or the other case, which is maybe your poor
using carbohydrate as a fuel.
So disclaimers aside, we'll get into a couple of them.
So should we think about these as informative and useful,
but not diagnostic?
Exactly.
We call this data inspired or data led and not data driven.
Right.
Okay, cool.
So number one, you want to think about just overall functionality.
Do you have a reasonable regulation
of your energy throughout the day?
Now many things could be going into this,
which is why these are not specific diagnostics.
But as a basic measure, we talked about blood glucose levels.
You know, a lot of people will say, again, you want that to be something like between 80
and 90 milligrams per desolate, or is a blood glucose level.
And if you can go look at the cutoff points for what determines to be pre-diabetic and
type 2 diabetic, et cetera.
What I can actually recommend,
this is, there's a little bit of science here,
actually, that I'll talk you through,
but a lot of this is my personal preference.
I generally want people to be at 85 or lower.
And that's because of a couple of things.
Number one, there's actually some papers that showed
any, every single point increase above 85 increases
your likelihood of developing type 2 diabetes
by about 6%.
Okay, great.
So technically while maybe 90 or 95
or even up to 100 are, you know,
in the quote unquote normative values,
that's one clue.
Again, it's not definitive by itself.
Does it mean anything?
You need to really pay attention to what increasing
by 6% actually means,
but it's a data point where I'm looking at.
If I actually then see symptomology,
and we run you through, maybe some questionnaires,
ask how you're feeling throughout the day,
and we see uncontrolled energy about.
So you're a lot of energy, then you get really,
really tired and swings.
Okay, another data point.
All right, and we may patch a few of these things together.
That may give me some clues. That being said, again, a lot of this rhetoric is used to then scare people off of carbohydrates, and that is, I want to be as clear as possible. That is not, not truly,
the only thing people should care about, right? It can be a thing.
It can also be unrelated.
There are reasons you could have blood glucose
concentrations at this level, or anterious swings
that are unrelated to carbohydrate ingestion at all.
So one test you can have to run, in addition to that,
if you're going to get blood glucose measured,
you can look at some markers we talked about earlier,
which are AST and ALT.
We talked about how you can look at that AST talked about earlier, which are AST and ALT. We talked about how you can kind of look at that AST
to ALT ratio before.
You can actually do the inverse, which is look at ALT and AST.
The kind of normative value there you're
going to look at is like 0.8.
I actually like to see it lower than that.
And that alone has been actually associated
with blood glucose dysregulation.
And so if you see multiple of these signs again,
we're looking for patterns and patterns and patterns in both in
our case biomarkers, symptomology and performance. And now you're if all three of
those things are lining up, you may have an issue. So performance wise, a couple
of little tests you can run. Ideally you have some sort of stand or work out
you do. And hopefully it's pretty objective.
So in other words, I run the same 15 minute loop
every morning for my cardio.
Oh, okay, great.
How long does it take you to run that loop?
Like, you could pick whatever distance.
It doesn't really matter.
What's your heart rate during that thing
and then what's your perceived exertion?
Now, you should be able to do that fasted
with very little drop in performance.
If you can do that, then that tells me you're fairly good at using a Fattas view source.
If however, the one day you go to do your standard workout and you feel awful fasting, that
may be another clue that perhaps you're not very good at dialing in that system. If you're recovery afterwards in terms of heart rate recovery is very long, it may be
another clue that you have poor utilization of fat as a fuel source.
The inverse can also be true.
If I give you something in the neighborhood of like 50 or so grams of carbohydrate and
30 minutes later, your face is falling off the table. That's a good sign
that you're in the opposite. You're actually very, very, very poor utilizing carbohydrate as a fuel.
And the reason I bring that up is that is equally a problem. We hear people a lot make comments
like, man, I have to stay away from carbs, I crash really hard if I do them. That has, what that
actually means is you're very poor at utilizing carbohydrates
as fuel. You're getting your sensitivity is way off. We should be able to have carbohydrate
at a reasonable dosage of 50 grams and not fall asleep 30 minutes later or have to run to
caffeine. So that is a sign in our opinion., again, now just my practical brain telling you is,
that's the sign of dysfunction.
We should be able to have plenty of carbohydrates through the day if we choose to, if we want
to for any reason.
Now of course, if you were to throw 150 or 200 grams of carbohydrate in your belly, you're
probably going to take a little bit of an energy hit after that, but we should be able to have
a reasonable dosage and not, you know, have to fall asleep afterwards.
What is one way that people can enhance their utilization of carbohydrates for exercise?
The reason I ask is I think I fall into that category.
I do consume some complex carbohydrates and fruit, post-resistance training.
And that tends to be when I'm hungriest for them.
But typically, unless I've just done some resistance training,
I keep most of my daytime meals relatively low carbohydrate.
And then in the evening, I prefer slightly less protein and more carbohydrate.
Because it has this effect of sedating me a little bit.
And I sleep well. And I know this runs against what everyone was taught, which is to not eat
carbohydrates late the day. But I like it because then I tend to wake up in the morning with
at least as far as I can tell. My glycogen stores not necessarily topped off, but certainly filled.
And I'm able to train fasted in the morning. And my favorite pre-workout
is consists of water and caffeine and electrolytes. And maybe some supplementation as well. But
I love training fasted. So there's actually a number of things. One little
sticky thing you threw in there is actually the use of caffeine. So that's another sign.
If you have to have caffeine to do your fast training,
that's generally another sign
you're not very good at using fuel.
So I use caffeine prior to resistance training workouts.
Generally, I don't need it for any kind of cardiovascular training.
Yeah, and when I say that, it doesn't mean it's bad.
It's just like another clue of this, like,
okay, you should be able to do this
without having to have caffeine to execute it now
Using caffeine to get a better result is sort of different as an ergo genocate. Um, we actually use
A lot of high carbohydrate meals at the end of the day a lot of the times for our athletes who are cutting weight
Or trying to reduce weight. So it is a fantastic way
To handle a lot of things and that idea that if you eat carbs late at night
Uh, that'll increase fat. So like that's all is so old and so well destroyed
Scientifically that that's not a concern. There's so much data showing in fact. There's so much data on
like eating timing is
Generally poorly understood about when you can eat and what you can eat eating in the morning
versus eating at night.
A lot of what we've heard there is stuff.
Maybe we just saved that for another day
because we're gonna get really far down
and that's about a week and that's it.
But yeah, so I think our plan is to cover that
in an episode on nutrition,
which is in this series.
The only thing that would add to it is,
you know, you hear about ingesting carbohydrate late at night. I should just say that at least in my series, the only thing that I would add to it is, you know, you hear about ingesting carbohydrate late at night,
I should just say that, at least in my case,
I'm eating the majority of my carbohydrate,
unless I trained resistance train early in the day,
in which I guess I post resistance training,
in the last meal of the day,
but for me, that's not really late at night.
That last meal is somewhere between 6.30 and 7.30 p.m.
It's just three or so hours or something like that before it's super-owned 10, 10, 30 or
so.
Yeah.
So it's not, you know, midnight bowls of pasta. I've done that too, but typically it's
not. So I think that people will be very interested myself included in how meal timing relates to
all of this, but yeah, let's
So how do you improve fat
Idolization, how do you improve carbohydrate?
Idolization, let's hammer both out really quickly
enhancing fat
utilization is as simple as
doing a little bit of work in a
either pre-fat and gested state
So anytime you ingest a nutrient prior to training, you're going to bias towards that nutrient,
right?
Which is almost what we were talking about earlier.
So if you want to guarantee you burn more fat, eat more fat prior to workout, now you're
not going to lose fat.
But what you're what you're effectively signaling is we have an over debundance of this fuel,
preferentially target this fuel.
Now the downside is that may actually hinder your performance.
That's typically only a concern for people
at a very high level,
fat is a slower fuel source.
So if you're relying more upon that,
your top end is going to come down a little bit.
And so you wouldn't want to do that strategy
prior to race if it is a carbohydrate dependent race.
In fact, we actually see long-term adaptations that would suggest that.
The enzymes responsible for carbohydrate metabolism will down-regulate, so you get worse at
that.
So not a great strategy there.
Carbohydrate would be the opposite.
If you have carbohydrate prior to exercise, you're going to bias more towards that. So a handful of things you can do, if your total caloric intake is simply managed, that's
going to take care of a lot of these problems.
An appropriate eating strategy, so the types of food, the combinations of food, all of those
things are going to make your post carbohydrate ingestion, bone.
A lot of the things can go away.
There's a little bit of physiology that has to be corrected for.
It's a little bit in one hand, you can go very deep here.
The real answer of how we would do this is if we see a scenario like that, we're going
to do a whole set of analyses.
We're going to go full labs, probably extensive blood panel, urine, saliva, stool, even.
And we're going to figure out
where is that glucose dysregulation coming from.
So a lot of people think like,
oh, it's a metabolism issue.
It might be.
And also might just be a flag
that something else is happening in the body.
So we're going to actually work backwards a lot
to try to figure out exactly why that's occurring.
It may be as simple as,
oh, you're eating a lot of your carbohydrates
without any fiber or protein.
And we know that that's important
because those will actually blunt the glycemic index,
like the rise in blood glucose.
So it could be a simple thing of this like,
oh, your combination of food is doing it.
It's not the total amount.
It may be something again,
more endogenous to the actual system.
It could be a heredition, it could be a breathing issue,
there could be a number of things.
So the way to get better at it is to simply train it
and specificities can here.
So if you wanna get better at managing your blood glucose
throughout the day, so that you're not feeling
those things, it could be a fuel issue,
but it could be a number of other things.
And it's just hard to go into all of them with with an our time constraint.
So the practical tool that I would say here is if you want to get better at
managing energy throughout the day, make sure that number one, your protein is stabilized,
makes sure, number two, you're ingesting your food in the right combinations,
ideally with some fiber and or some protein or both.
That alone will help stabilize a lot of the problems.
Then you need to train at a high intensity.
You want to get better at using carbohydrates as a fuel,
train at a higher intensity and have carbohydrates
right before the workout.
We'll do that a lot if we see folks who are,
I kind of walked you through the test of identifying
if you're not very good at using fat as a fuel.
The test for not being good at using carbohydrate as a fuel is both that eating test I talked
about, as well as performance.
If you're a very, very, very slow starter, it's just like really hard to get going, that
generally indicates you might be in a situation where you're not very good at using carbohydrates
as fuel.
So we're going to practice that.
We're going to have a pre carbohydrate, pre-exercise carbohydrate meal. So we're going to practice that. We're going to have a pre-carbohydrate,
pre-exercise carbohydrate meal,
then we're going to do higher intensity stuff.
Not the point of making you sick
and digestive issues, all that stuff,
but we want to get better at using carbide rates
as they fuel faster.
If you want to get better at doing the opposite,
then you do that opposite, or either again,
using fat prior to the workout, knowing your peak performance
is going to go down a little bit,
but you're investing in adaptation, right?
So it's not about that workout,
it's about what's gonna happen six, eight, 10 weeks from now.
Investment is a way of anything about it.
Or you could bring in some fasted training.
And so I wanna really make sure I clarify
when we were talking about earlier,
I'm not at all against fasted training.
It's not, it works.
It's just isn't required for
fat loss. It isn't required for fat adaptation. It is a great option though. If you want, what
I was hoping to do with that conversation and maybe I didn't articulate that well is to
not restrict people, but is to open you up. And at least you have a lot of options. If
you like to do fasted cardio, amazing. It is great. If you hate it, you don't have to. You can reach the same performance goals,
the same physique goals without ever doing it. If you love long durations, study, state stuff,
it is great. If you hate it, there are other options higher intensity stuff. Again, if we're just
talking about fat loss. So I hope now that that's a little clearer
in terms of the same thing with nutrition.
If you like higher carb, great.
If you like lower carb, these are all great.
You have options and you don't have to fret so much over,
oh my gosh, I have to do this thing a certain way
and I absolutely hate it.
You don't have to worry about it.
Hit those concepts and you'll be fine.
A few minutes ago, you mentioned that if we ingested given macronutrient fat, then the
body will preferentially use that fuel source.
If you ingest carbohydrate, we'll use that fuel source.
Is it always the case that the body uses the ingested macronutrient prior to using glycogen?
I have to imagine it's using both. I mean, if I were to have some carbohydrate before doing any kind of training, the muscle
still burned glycogen, right?
Or do they have some way to register the amount of circulating carbohydrate that would allow,
or available carbohydrate in the form of foodstuffs that would allow them to not tap into their own muscle fiber stores of glycogen.
All right, so the way that we derive energy for exercise or basic maintenance, a little
bit about cellular physiology.
So, you've got a couple of organelle instructors that we need to pay attention to.
The first one is the nucleus, that's Hold your DNA.
The second one is the mitochondria.
And then everything outside of that, you've got all these other organelle that do a bunch of things like ribosomes for protein synthesis
etc etc. All right now
When you want to produce energy for exercise
Anytime you hear the word anaerobic you automatically understand we are meaning without oxygen
All right, great that all happens in the cytoplasm
The cytoplasm is that space that is not the monocondria, not the nucleus.
So it's the space in between everything else.
This is like jelly-like substance, so sounds there.
So anaerobic metabolism happens there.
Every single aerobic metabolic process happens in the mitochondria.
All right, why is that important?
If I go to create cellular energy,
and I need it the fastest possible,
I'm going to go for phosphocreative,
because it is stored directly in the cytoplasm.
The stoichiometry is one to one there,
which means for every mole of phosphocreative,
I burn, I can create one ATP.
It's one to one.
It is incredibly fast,
but it is very limited
because think about it.
How much of that could I possibly store
in the small size of the cell?
That's it.
If I need energy past that point,
now I'll start using muscle glycogen.
Because that is also stored in the cytoplasm.
So it is right there.
The stoichiometry is not one to one.
It's a little bit higher, probably like four to one.
So for every molecule of glycogen,
you burn your going to get something like four, yes.
Like some small number of ATP out of that,
which is great.
But again, you're running into a storage problem.
How much can I possibly store inside a muscle cell?
It is very, very fast, much more effective
than muscle creatine, but so there.
If I then want to metabolize any
form of fat, or if I want to complete the metabolization of carbohydrates, I have to start transferring
into the mitochondria. Now, I start getting whole hosts of ATP. If you were to fully run
through this thing, which I'll talk about a second, I'm the TCA cycle, a Krebs cycle. You'll get now something like 28 or 30 or 35
and down to depending, ATP per.
So the energetic output is much higher.
Okay, so here's exactly what happens
and I'm gonna walk you through this
in the form of carbohydrate
and then I'll come backwards and go through fat.
So remember, carbohydrate, it is one carbon molecule that has been hydrated, so it is one to one.
So the actual chemistry here, it is C H2O, one carbon, two H, one O. Glucose is a six carbon chain. So the chemistry here is C6 H12 O6, 6 carbons, 6 waters. Very simple.
That's a carbohydrate. Right. So you can imagine if you're watching on the video here, you'll
see my fingers going out, so I'll try to make sure I explain it to you. I'll just
listen in easy fashion. So you've got this chain of 6 carbons that is in front of you.
And the very first step to metabolism is you snap that thing in half.
So you break into two separate three carbon chains.
Now, in doing that, you got a little bit of energy
because you broke that one bond,
but not a tremendous amount.
This is called glycolysis.
So lysis being the split, you know, glyc...
You split glycogen up.
Got a little bit of energy of that.
All right, you formed this three-color carbon chain
called pyruvator, pyruvac acid.
Okay, there's differences there, but don't kill me.
General audience, friends, all right?
I gotta give this to everybody.
So you got a little bit of that.
Now, you can't do much past that
besides rip one more carbon off of each of those three carbon chains.
So I've got two, three carbon chains. So I've got two three carbon chains.
I'd be careful how I do this with my fingers, so I don't flip you off here in a second.
But I burn one more off of each.
I get a little bit of energy, and now that little two carbon chain, I have two two two
carbon chains, those are called acetil CoA.
All right, amazing.
I have now completed an aerobic play callysis.
I've got really nothing left I can do here.
I made a little bit of ATP.
Now, wait a minute.
I have now freed two carbons.
Because, remember I started with six,
and I swidded them apart,
but I didn't have two, three carbon chains.
I burned one each.
I've got two free-floating carbons.
I have to now do something with them.
My body will not let me go through that last process
unless I've got a plan for that free carbon because I can't break it in half. Amazing. Here's
what's going to happen. If I have those three carbon molecules and I don't have anywhere
I can put that carbon, you're not going to go through that process. It's going to stop
it. You're going to stop it.
You're going to start building up pyruvate.
Now, at the same time, you're breaking ATP for fuel. That's called ATP hydrolysis.
You have water that comes in, you have a dendecine,
and three phosphates, that's why it's called ATP,
dendecine triphosphate, one, two, three.
You break one of those phosphates off.
There you go, there's your energy.
So now you have a free-floating inorganic phosphate, one, two, three, you break one of those phosphates off. There you go, there's your energy.
So now you have a free floating inorganic phosphate
and an adenosine dye phosphate.
So two over there.
Amazing, that actually results because you use water for it,
results in a free floating hydrogen ion.
Okay, just have to trust me hydrogen H2O.
Hmm, any idea what a free floating hydrogen is?
Um, it's gonna, that's acid.
Yeah, I was gonna say it's gonna increase acidity.
That's what I said.
For anyone that's ever measured pH,
what you're really measuring is the amount of hydrogen.
Potential hydrogen, that's what pH is, right?
100% or there's two definitions of pH,
but you get, that's one of the two.
So, are you gonna tell me this is related to the, the, the burn?
We're going to get close, right? So I've got a bunch of free floating.
You got the phosphates, which are actually problem to probably more of a problem than people
realize, and that hydrogen. What are you going to do with that hydrogen? Well, one thing you can do
is actually ship it over to pyruvate and bond it there.
We have a special name for that little molecule when you have pyruvate and you have a hydrogen attached to it. You know what's called?
Hydrogen peroxide lactate
Lactite lactocassid. This is that whole system, right?
Again, I'm skipping some steps, steps making a little of mistakes here, intentionally folks, just to make this assumed.
So what happens when you start running a bunch of anaerobic glycolysis, you start seeing
massive rises in lactate.
Cool.
Not lactag acid.
Right.
Right.
That's why we see associations between a lot of lactate and a lot of fatigue, but the lactate
is actually not causing the fatigue.
The lactate is actually sparing you
from having a bunch of free floating acid.
It's also can be then used directly back into the muscle
because as soon as you bring in enough oxygen
and you can take that hydrogen back off of it,
you've now turned it right back into pyruvate
and you can run it through this whole cycle as fuel
that I'm about to do.
You can actually actually ship it out of the exercising muscle and ship it into a non-acercising
muscle and then go backwards and make glucose.
What actually liberates hydrogen from lactate?
You like chemically?
Yeah, so what liberates, what are the stimuli that can take hydrogen off the pyruvate and
then in other words, to reduce lactate and free up that
hydrogen.
Oxygen availability.
So in fact, one of the major places that you ship hydrogen to, or one of the major places
that you ship lactate to is your heart.
Because it's what we call like the ultimate slow-church fiber.
And it has a ton of freely available mitochondria, which have a ton of access to oxygen so it can actually
then go to it, form water. The HG will be used to form water and now we have a place to
store the hydrogen. Got it. Right? Cool. So as a result of anaerobic like
halusis, we have made a little bit of ATP. We've created a lot of waste and we don't have anywhere to go with
these end products. So when you do anything of a higher intensity and it says, I need energy
fast, you're going to go to this system first, right? Right? Past ATP because it is the fastest
place to get energy, but you're not going to get much of it and you got to deal with
the waste products. Boom. Right back to the beginning of our conversation.
Endurance is about two things, energy production
and waste management.
And we're right, fatigue buffering, this is it, right?
How well can you handle the elevations in hydrogen,
right, drop in pH?
And what are you gonna do with these products?
If you want to fully metabolize a carbohydrate,
you then have to take something
to something with those pyruvates
or those acetylCoAs.
What you're going to do if oxygen is available,
you will take those things
and ship them into the mitochondria.
They have to go through some cell walls
and some other things like that,
but they're going to get inside there.
Once they're in there,
that two carbon acetalCoA
runs through this entire cycle
that we call the Krebs cycle.
That's this really interesting place.
That's where B6 and NMN people are like that's where that whole stuff starts to kick
and all your B vitamins basically run that entire circle.
You're going to start off the top.
You have a bunch of fun stuff going on.
But as a part of that circle, you're going to pull off some hydrogen ions.
You're going to send these to what's called the electron transport chain.
That's where you're going to get a ton of ATP out of.
And as a result, about halfway through the turn, you're going to pull off one carbon.
And about halfway through the other, but almost the other way through the finish, you're going to pull off the second carbon.
So you're going to take the second acetil CoA, run that entire thing, same through as well.
And so what we did is we started off with a six carbon glucose chain.
We split it
in half. We called those pyruvate. Made a little bit of energy because we broke that one bond of
those two carbons that are in the middle. Cool. Those two, three carbon molecules. We pulled one
carbon off of each. We brought in, sorry, we moved those into the mitochondria. We brought one off.
We took a breath, brought in some oxygen, bonded that, breath took out two CO2 exhales.
We ran the acetal coA through the Krebs cycle,
one, two carbons per turn coming out of CO2,
so we had six carbons total, and we started,
and we exited with zero carbons.
Now we have fully metabolized
a molecule of carbohydrate.
That required an anaerobic start,
and an aerobic finish. If you don't have a lot of
mitochondria, large mitochondria, high functioning mitochondria, you're going to limit your anaerobic
performance because you're going to get, they're going to run that door full very, very quickly.
You can't go past it because hydrogen will build up way too fast. And one of the things that we know is both temperature and pH run enzyme function.
So they're going to stop.
You want me to be able to run through in fact that ATP hydrolysis phase,
even if I gave you a whole infinite supply of ATP,
if I put enough acid in there, it would stop working because the ATPase enzyme needed
to split, it won't be able to run in a highly acidic environment or a hot environment.
Yeah, at some point, perhaps today,
perhaps in the future discussion,
but still not too far from now.
We could talk about the role of temperature
in the, in pyruvate in terms of its regulation
muscle contraction,
but I want to make sure I understood something correctly.
You mentioned these two parallel fuel systems. One is essentially
anaerobic, and the other is aerobic. You said that if we can't pull enough, if we can't break
enough bonds, then we limit our anaerobic capacity. I would have thought, given that the mitochondria of the site for essentially for aerobic metabolism,
that we would be limiting our aerobic capacity as well.
Perhaps you could just clarify for me how these two things are divided, or is there not
a clean division?
Is it not an either?
No, in fact, I think it's better to think of these things rather as two separate parallel things as one big cycle. They're one gear turning the next.
Being compromised in one will compromise the other. That, I should say, reminds me of what you
said earlier, which is the the bicycle gear analogy. That works great. So if you short circuit one,
basically the chain can't move. That's fantastic. Okay, so indeed they are running in parallel,
but they are interdependent.
Yeah, well, they're actually not even running in parallel
because they're actually fumbling to the same endpoint,
right, which is like, if you're going to come
from the anaerobic glycolysis route,
or you're gonna come from the fat route,
which I'll talk about in a second,
they're both going to be limited in the mitochondria.
So when that thing's full, it doesn't matter.
You can't run either system, right?
So it is more of like a, again, if you're running the bike gears, it doesn't really matter
if the back one's larger or smaller, because if either one is limited, your toast, because
they're running on the same system.
You can, you can sneak a little bit here and there, but not much.
You also really nicely highlighted how lactate, this thing that we think of as a limiting factor,
like the burn, it gets in the way, and it's the thing we need to stop and buffer and all
sorts of things. It's actually really a fuel.
It's a tremendously effective fuel.
Yeah, is a strongly preferred fuel, actually.
This is a very classic case of association, correlation versus causation.
So the original actually, there's a really cool history on lactate, but it was originally
found, I think in Germany, pardon my history, there, somewhere in Europe and hunted stags.
So one of the things is they sort of realizes,
like if we harvested a stag in a resisted state
when it didn't know what we were there,
versus if we chased it and it was ran down,
that these lactate concentrations were significantly
higher in the latter situation.
Therefore lactate started immediately
getting this association between high fatigue points,
and it is easy to measure.
If you're to do any sort of lactate test, any sort of metabolic test, you will see as fatigue increases,
lactate will also increase. The assumption there was then, oh my gosh, it's the cause.
Now we know, like, again, it's not the thing, it's in large part trying to buffer the negative
consequences of ATP hydrolysis and some other things.
So it is certainly playing a part in that role, but it is not a core driver.
It's also why you don't need to worry about doing things to, quote, unquote, reduce lactate
in the muscle after exercise or to clear lactate or any of those things.
You may still want to do those activities, but not for that reason.
Lactate is fine. You're actually going to use it, and again, the neighboring exercise muscle fibers
in the same muscle.
Another muscle, you can send it actually to the liver, and it can actually go through gluconeogenesis,
and it can actually replenish liver glycogen just as a fuel source, or you can send the harder any number of sources.
You can also just put it in circulation, put it back in the muscle,
and once enough oxygen is there,
you can just kick it right back into either glucose
or glycogen.
It's totally fine.
So it is obviously clear though.
Once that number gets very, very high,
other things are going to be happening
that are causing a lot of hurt.
And this is your managing waste, right?
It is really an issue of managing
what am I gonna do with all this extra carbon?
What am I gonna do with all this extra
intergalactic phosphate and some other nasty byproducts?
But that's the thing you have to deal with.
I'd love for you to teach me how different ratios
of fuel sources are used,
depending on how long I happen to be exercising.
For example, if I do a very short bout of exercise, typically, that's correlated with a higher
intensity output. I suppose I could jog for one minute, but here I'm thinking about sprinting
for one minute or less, which fuels are used? Is that mainly driven by fat, stores, by
carbohydrate stores? Is it driven by dietary fat preferentially or carbohydrate
that I've ingested if indeed I've ingested those or protein for that matter.
And then as we transition to exercise, it goes a little bit longer, anywhere from three
to five minutes, how do those ratios change?
And as we transition to longer duration, what most
people think of as endurance exercise, but longer duration output of, you know, 20 minutes
or more leading all the way up to full marathon, how does that change the ratio of fuel sources
that are used? And I'd be particularly interested in distinguishing between carbohydrate, fat, and protein that's ingested, so coming from food sources,
or carbohydrate, fat, and protein
that are coming from storage sites within the body.
Okay, great.
Let's start at zero seconds and run all the way through
the marathon, and we'll flag the distinctions
where they start changing.
As soon as you want us to create muscle contraction
and power, the very first source of energy is fossil
creating. That's going to power you for zero to maybe say eight to fifteen, twenty seconds of
maximal exertion. And that's in coming from the muscle fibers themselves. Yeah, that is actually
stored in what's called the cytoplasm. So this is a little area or space in the muscle fiber
that's sort of like in this jelly-like substance. And it's nice because one molecule of phosphocryptin
gives you one molecule of ATP.
So it's not a big energy output,
but it's very fast because it is stored right there
in the local exercising muscle.
Right, now, if you need energy, pass that point.
Say, you know, 10 or 15 seconds up
to maybe a couple of minutes.
This is now you're gonna have to transition
because you're gonna burn through that phosphocryptin and it's gonna be out. You're gonna have to move a couple of minutes. This is now you're gonna have to transition because you're gonna burn through that phospho creatine,
it's gonna be out.
You're gonna have to move to now carbohydrate metabolism.
This is what we call anaerobic glycolysis.
So there's two phases of glycolysis.
Now glycolysis itself means glucose burning, all right?
So this means we're using carbohydrate as a fuel source.
So initially, when we start off this cascade, which is going
to take us again for a couple of minutes, carbohydrate utilization comes first from the
exercising muscle. So it's very similar to phosphocreatine that way. If you start running
low on it, you can actually start pulling blood glucose. And if blood glucose gets low,
you'll have to start getting glycogen from the liver to keep that up. And we've sort
of covered that conversation.
All right, so a little bit of chemistry here.
Just give me a little bit of room here.
So now, remember, a carbohydrate is a carbon molecule that has been hydrated.
So one carbon attached to one water, and remember water is H2O.
Most of the time we're talking about glucose, it is in a six carbon chain.
So six carbons attached to six water molecules.
All right, great.
When I go to split this up through anaerobic glycolysis,
it works a little bit like this.
So you've got this six carbon chain.
The first step is to snap that thing in half.
You're gonna make two, three carbon chains.
Now we broke one bond right there,
so we got a little bit of energy,
but not a tremendous amount. At the end of anaerobic glycolysis you're going to net something
like three or four ATP. So more than you get from the phosphatucrysis
is quadruple. But still not very much. There's another major downside that's coming in a second
to this system. The upside is it's fast. Now, why don't actually one adaptation we get to training
in this style is you'll increase your ability to store glycogen in your muscle. Which is
great, right? We can actually biopsy you and measure the amount that you store and a training
adaptation is awesome. So you're able to sustain the system longer. So perhaps 90 seconds
into your interval training, you hit a fatigue point and now you maybe can extend that to a hundred or a hundred and fifteen seconds simply because you're storing more glycogen in the muscle.
Before we have to end then go into the blood and get in the form of glucose. So that's great.
So we've got this six carbon molecule and we split this in half, we got that little bit of ATP.
And now we're in this little tricky position because this three carbon molecule
is what we call pyruvate, pyruvate acid.
And again, chemistry folks, I'm skipping some steps,
I'm gonna intentionally make some mistakes here.
I'm making sure the entire world listening
regardless of where they come in can follow me here, okay?
So don't burn me on the details.
Right, you've got this pyruvate.
The problem is you can no longer do anything with that.
Like all this is over.
You've got to make a choice.
Right, in order to make something out of those three
carbon molecules, you've got to ship them
to the mitochondria.
As you said, that is the only place of aerobic metabolism.
Right, we cannot do aerobic metabolism anywhere else
until we enter the mitochondria.
So anytime we cross that barrier, we know we've automatically switched from anaerobic to aerobic.
Here's the problem.
If you were to take one more carbon off that three carbon pyruvate, you have to now do
something with that carbon waste.
So before when we split the six carbon chain, we didn't actually leave any carbons free
floating.
We just split a two molecule in half.
When we go to split from pyruvay and make it into this two carbon molecule called acetyl
CoA or COA, now we've got a free floating carbon.
We have to have a strategy for that because that's going to increase the acidity level.
Any enzyme in our body that works to create fuel is very pH sensitive.
So if this thing, if pH gets off either high
or low, these enzymes can't work.
And that's really, really important
because even if I were to give you a direct injection of ATP,
remember that's that energy currency,
that's the only way we can actually form energy.
I guess I'm able to clarify,
anytime we're using phosphocrytine or glucose
or fat, which we'll get to a second,
we're not actually getting energy for exercise by breaking those down.
We're getting energy that we can use to then make ATP.
We break that ATP down.
That's what's actually powering muscle contraction.
You can go back to our previous episode where we walked you through the detail of the muscle
contraction.
But that's what we're after, okay?
So in the case of pyruvate, if we split that off, we have got to deal with
that. And the only way, and the best way we can deal with that is oxygen. Remember, we're
going to breathe in O2. That O2 is going to combine with that free floating carbon makes
CO2. We're going to exhale that thing out. That's our waste management strategy. But that
has to happen in the mitochondria. Remember, if we're using oxygen, it has to be in the mitochondria.
So if we have the ability to ship pyruvate into the mitochondria or golden, but what happens
if we don't?
Why do we not?
Well, if we don't have enough mitochondria or mitochondria are too small or they're too
far away, or we don't have sufficient oxygen availability.
Why don't we have sufficient oxygen availability?
Because we created the pyruvate too fast,
and the demand in the mitochondria is exceeded
by the buildup of pyruvate.
So now we're having this giant backlog,
and this thing fills up fast.
We have a couple of strategies here. Well, when
you're going through ATP and you're splitting, it's called ATP hydrolysis. In, I'm doing
that. Remember ATP is a, what, a dentists in molecule and then the tea part is triphosphate,
one, two, three, which means you have three phosphates attached at the end. When you break that
phosphate off, that's where you get to energy. And so now you have an inter-gatic phosphate and an ADP, a Desson dye phosphate, too.
That process requires water, it's called hydrolysis.
As a result of that, you then have a free floating hydrogen.
And as you will know, that is acid, right?
That's potential hydrogen.
That's what that means.
And so, you've increased the acidity
in the muscle by breaking up all this ATP. And so, uh-oh, we're building up acid. We have
building up pyruvate. We know I'm nowhere to go with it. And we can't cleave off a carbon,
because now we're just going to exacerbate the acid increase. So, what we can do is we can
take those hydrogens that we're building up and store them on the pyruvate.
A pyruvate that's holding an extra acid has a special name and we call that lactate.
Right? So that's why we see this build up of lactate. So one of the downsides of anaerobic eye
causes is an incredibly high rate of waste production. Now lactate is not the cause of fatigue.
In fact, if you think a little bit more carefully about what I just said, it's actually stopping
you.
It's what we call a acid buffer.
You can actually use it for a bunch of everything.
You can ship it to a neighboring muscle fiber in the same muscle that's not working.
You can ship it to the liver.
You can ship it to the heart in a bunch of other places.
And then you can actually just work backwards. So if you ship it to, for example,
the heart, and it's got a bunch of mitochondria that are free, you can bring in the oxygen, attach it
to that hydrogen, make water, and now you're right back to pyruvate. You put two pyruvate back together,
and now you just make glucose. So you can actually store it in the liver. This is a
process called gluconeogenesis. Do this fancy thing called the Choricycle, this is a process called gluconeogenesis through this fancy thing called the Corey cycle,
which is what the proper cycle here is.
So you can use it as a very potent fuel source.
In fact, a lactate is a tremendously valuable fuel source.
I'm not only for exercise,
but for cognition and a bunch of other things.
So lactate, in fact, this is why,
if you've seen any of the research about pre-exam testing
exercise, you'll see a noticeable
increase in exam scores if you do a 20-minute-about-of-exercise prior to taking the exam.
And it's largely in part probably because of things like elevations in lactate.
How intense of exercise would be most beneficial?
I don't know that exact answer.
I just know that generally any form of exercise is good, but if you were to reach a reasonably
high heart rate, you're probably going to see.
In fact, there's an acute and chronic adaptation here.
So folks at exercise have better memory retention, score, and so on, and so on, but then also
doing it prior to that exam, make sure you're recovered and rested back down to straight,
but you'll generally perform better.
Previous guests on the human lab podcast, who's a psychology professor and neuroscientist
and also dean of College of Arts and Sciences at New York University, NYU, Wendy Suzuki,
is religious about daily morning exercise, specifically for this purpose of enhancing learning
and memory. It has a lot of really beautiful data. I consider one of the real pioneers in this space. So if people want to
learn more, they can look to that episode or Wendy's work. We can provide a link to a couple
of the papers. But this is fantastic in that it's incredibly clear. I think for the first
time, I'm understanding what what lactate is really doing. And it's dispelling a lot of myths
that I think I and a lot of other people arrive to the discussion about lactate with. What
happens when the bout of exercise extends longer?
Amazing. So if we want to continue past that point, we have to have some sort of strategy
to get through it, right? We're stuck, we're out of gas.
We have to then ship it to the mitochondria,
and now we're gonna enter what's called a Robic,
the glycolysis, and this is gonna take us anywhere
from, again, say that 90 seconds of all that work,
up to really 20, 30 minutes, in fact,
it really will take us to unlimited.
If you look at a highly competitive marathon runner, even
those that are running say you're two hour marathon, those folks are burning up to 80%
carbohydrate. It is not a fat burning thing. And the reason is fat metabolism is way too
slow. It provides a lot of energy, but it is incredibly slow. If you're trying to run
a four and a half or so minute mile, repeated 26 times, you have to be moving fast.
Are they ingesting carbohydrate as a fuel source during the race?
Unless you're on the team, you don't know.
They won't really tell you these are sort of trade secrets.
It would be, I would say, fairly rare to not have something.
There's a bunch of different strategies.
If you're going to go really long, like some of these,
like cycling, where the races will be several hours,
then you actually might go to some fat as fuel sources.
I know a lot of cyclists are using ketones
and things like that.
But traditionally, most endurance folks
are gonna buy us heavily towards carbohydrate.
Now, in one respect, you're not going to run out of carbohydrates
until you're many hours in. These folks are a unique case, but the average individual
who's doing an hour, hour and a half cardio even, you're not going to be limited
by your carbohydrate stores. You're going to be just fine. You're going to be limited by some
other things, which will maybe sort of break down here in a second, but you're going to be just fine. You're going to be limited by some other things, which will maybe sort of break down here in a second,
but you're going to be fine there.
A lot of those folks will take carbohydrate,
though, at very specific intervals.
You do want to be careful, though,
of ingesting too many fast carbohydrates prior
to your exercise spell.
We actually have this little thing
that's called the insulin glucose double amy.
And what that means is,
when you ingest carbohydrates
immediately your blood glucose goes up
and that's depending on the type of carbohydrate
and things like that.
Well, the same thing happens with exercise.
And so what happens is insulin wants to start
pulling glucose out of the blood.
At the same time muscle wants to start
pulling glucose out of the blood.
And so we have this giant bolus of carbohydrate come in
and then all of a sudden our blood sugar crashes. And so if you're going to be doing so your first half marathon or something
like that and you're in those giant corals where there's like you know 100 people waiting to go
and you're standing in front 45 minutes, you may or may not want to slug down like three or four
bananas in a bagel and and and honey and and you probably don't need that.
Now, not everyone experiences this double whammy,
but it has been shown in the literature to happen to some people.
So you want to just be a little bit careful.
An easy way to combat that is just practice
exactly what you're going to do in your race
in your training.
That's the simplest advice ever,
but you'd be stunned how many people do things
during the race that they've actually never done in training.
I suggest people do exactly what you describe also for any kind of
cognitive testing.
Of course.
Before a big exam is not the time to discover whether or not you can handle twice as
much espresso or take a new tropic for the first time or no or change anything.
I mean, if indeed the score on that exam is meaningful to you, keep
things regular.
So, to recap what we've done here is we started off in the cytoplasm with this glucose
molecule that is six carbons. We took that thing, we split it in half, we called that thing
anaerobic like all this, we made a little bit of energy, but not much. We take those three
carbon molecules, we ship them into the mitochondria, we take each one of those, we clear off one
carbon each. Those carbons, we take a breath in,
we attach them to oxygen, we exhale them,
get rid of that energy.
We are now fully into a robooc glycolysis.
Each one of those two carbon molecules,
we run through the Krebs cycle.
Each round of the Krebs cycle burns one, two carbons,
so we go one, two, one, two,
and now we've gone from six carbon molecule
all the way down to zero.
We used the hydrogens that we pulled off of that Krebs cycle run So one, two, one, two, and now we've gone from six carbon molecule all the way down to zero.
We used the hydrogens that we pulled off of that Krebs cycle run to go to the electron
transport chain.
From there, we made a whole bunch of ATP.
And so we have now fully metabolized one molecule of carbohydrate.
And the end product of all of it is simply ATP, water, and CO2. Beautiful. And leads me to the conclusion that most everything is really about
utilization of carbons and exhaling CO2. Is that how I should think about bookending what
you just described? This is why we started off the conversation with the Circle of Life.
This is really a carbon gain. This is why we call chemistry with carbon organic chemistry.
That's what the whole thing is about.
Any living being has to run through metabolism.
It's all a carbon game.
Any living being has to use ATP.
This is all just a big fancy game.
How do I make ATP and handle the waste?
Remember, endurance is all about waste management,
fatigue resistance, the same thing,
and energy production.
We're playing a game here.
The whole game, bring in energy, use it,
mitigate waste products.
So when thinking about aerobic exercise,
or long duration exercise, in this case anything
longer than five minutes for that matter, five minutes all the way up to an ultramarathon.
The breathing associated with endurance exercise, the heart beating, which of course is associated
with the breathing in vice versa, it's really all about bringing oxygen into the system that then allows those carbons to be used
and within the mitochondria specifically and then carbon dioxide to be exhaled as we work through
the carbons of the sort of beads on a string. Is that right?
Unless you're moving incredibly fast for a very long time. And we're talking probably north of 90 minutes. Endurance
is really not a game of making sure I have enough fuel. It is simply managing the waste
production. And that's exactly what you described. You need to bring in the oxygen so you can
handle the carbon that's building up as a result of both the anaerobic anaerobic like
halces. That's our game here.
If we start talking about endurance events longer than that,
now we do have to start worrying about
running out of muscle glycogen,
running out of liver glycogen, et cetera,
or if we are at that two hour marker zone,
we're moving very, very, very fast.
But anything south of that is just managing carbon buildup
and we do that best through oxygen utilization or getting more efficient
and having a higher capacity for our anaerobic side. So we can do that by having either more glycogen
in our muscle, so that lasts longer, or building better acid buffering systems. And there's a whole
line of supplementation that are specifically acid buffers, there's a whole line of supplementation that are specifically acid buffers, has a whole
line of training, there's a whole line of breathing to manage this step.
So we have a lot of strategies where we can maximize endurance.
All we have to do is go back to the earlier part of our talk, which is figure out what's
the actual limiting step and then train according to that or do your strategy, your nutrition,
your supplementation that defeats that limiting factor.
For an example, if you are trying to maximize your performance in this 20 second, maximum burst,
and your strategy for that was to make sure your muscle glycogen is saturated,
it's probably not going to help a ton, because you're not going to be limited by total fuel. You're going to be limited by your ability to buffer acid.
However, storing more glycogen in your muscle and preparation for a marathon is a tremendously
effective strategy, because that will become a limiting factor.
So what we can do, actually, next, if you'd like, is we can just walk through these and
look at the individual limitations where the failure point happens, and then that effectively will outline your strategy for improving them.
So you taught us about carbohydrate utilization as a fuel source. What about fat and what about protein?
Great. I'll start with protein because it's easy. It is generally at best going to represent 10%
is generally at best going to represent 10% of your energy output. Now that will grow over time in terms of if you did a several hour about a exercise.
When you started doing it, you might be using 5% of your energy from protein and then that
micro to 10 or so.
That happens because you start running low on muscle glycogen.
You start running low on liver glycogen. You start running low on liver glycogen, you start
then having to pull in energy from another place. So like as those numbers go down, you'll see
an increased uptick of energy from fat, as well as protein. Having said that, it's not a tremendous
fuel source. It is only a rubric, so it has to be oxidized. Those are the same thing. When I say oxidized, you use oxygen to burn something to make a fuel.
So it's not a significant contributor to energy in that regard.
And unless you're talking ultra-marathons are longer.
And it is also not something that can enhance performance.
And so we don't really need to talk much more about it than that.
In terms of fat as a fuel source, now here's the fundamental difference.
While carbohydrate starts anaerobically and finishes aerobically in the mitochondria,
you're using mostly the carbohydrate in the exercising muscle tissue.
Eventually you can pull from blood and then you can pull from the liver.
With fat, you have a tiny amount stored in the muscle, intramuscular triglycerides.
But the overwhelming majority of fuel you get from fat comes systemically.
And so now we have a fundamental difference.
We actually literally have a time problem.
I can get energy from carbohydrates faster because it is directly there.
If I go to pull it from fat, I've got to pull it from the rest of the body,
which is why somebody who loses fat
loses it from their entire body,
despite the fact that they may be only
exercising a couple of parts.
So think about a runner,
someone who lost a lot of fat running,
you don't see them just lose fat in their legs.
It comes from their face and their neck and everywhere.
Why?
Because what you're going to do is pull fat
from the entire system.
You're going to break it down through a process
called life polices, which means you break it down
from the stored form.
You put it in the blood as that glycerol back bone,
which is that three carbon backbone
and the individual fatty acids.
It's gonna float through the blood.
There's a seven step system here,
but we'll skip it for now.
It's gonna have to get then up taken into the muscle in the muscle, then it has to get
taken up and run into the mitochondria. Now, that backbone, that three carbon glycerol
backbone is actually going to function almost exactly like the three carbon pyruvate. Just
get it into the mitochondria, clear off one carbon, run it as stuccoate, bottoming, but
a bone. Exactly. Same thing.
Super easy to metabolize, small enough to go through the mitochondria membrane.
The fatty acid change become a problem.
So if you have a chain that's longer than are eight or so carbons, it has to actually
go through a special transporter on the cell wall to get in.
And that's going to be limited by a thing called carnitine.
And you're probably familiar with that as a supplement.
You may have talked about it.
There's a lot of places that make it.
That's going to be limiting factor.
If it is a smaller, what we call a short chain,
or even a medium chain,
for a glyceride, which a lot of folks have heard of MCT,
that's what we're talking about.
That can actually go directly through,
because it's small enough to pass through,
and you can use it immediately as an air resource.
In either case, the way that you finally metabolize
a fatty acid is a process where you would go through
and cut off two carbons at a time.
Why would you cut off two?
Because you're trying to make that two carbon assasinal coase,
you can run through that Krebs cycle again.
Because you're cutting off two carbons at a time,
we have a special name for that oxidation process.
It's called beta oxidation.
That's exactly why we call it beta oxidation.
Two carbons in, you cut it off to make that acetokoe.
So you can notice the oxidation pathway,
the electron transport pathway, is identical,
whether you're talking about the carbohydrates or the fat.
In fact, it doesn't even matter.
More to our point, if we're talking about simply fat loss,
it really just is about running that electron transport chain,
whether it came from a carbohydrate or original source,
or a fat or original source.
It ends up in the mitochondria as basically the exact same thing.
It then ends the end of metabolism as the same thing.
Remember, the final endpoint of carbohydrate metabolism is water, ATP, and CO2.
Do you want to guess the final endpoint of fat metabolism?
It's water, ATP, and CO2.
So practical applications here.
If you want to maximize fat loss, what type of training is best?
It really doesn't matter.
If you enjoy longer steady-state stuff, fantastic. If you enjoy intervals, amazing.
If you would like to do a combination, that's my personal preference.
That's great too. You have a ton of options. Pick what you think is a combination of challenging.
Not all exercise should be easy, but you will actually enjoy somewhat or you're willing
to accept. Anything that you absolutely hate, don't do it. Sometimes is very, very, very
difficult to do high intensity training.
You have to really be interested in doing it.
If not, it ends up turning into like moderate intensity training.
You sort of just check the box.
And it doesn't work that well if you're just checking the box.
So if you're like, man, mentally, I don't have it in me today to get to a high heart rate
and throw up and all that stuff.
Cool.
But you can just get to some moderate study state stuff.
Well, that's a win.
Great. If you're like, oh my gosh, more than 10 straight minutes, and I'm so bored, and you're
all maybe you're also like, I don't have 45 minutes. I got to get this done in eight minutes.
Great. Go do some high intensity intervals. Either option will be equally effective.
As you mentioned earlier, exercise is useful for aesthetic changes, functionality, and for longevity.
But when thinking about exercise specifically for fat loss, I do have to ask this question,
I often hear from people that they prefer one type of exercise versus another for sake
of fat loss because certain forms of exercise make them very hungry.
I'm wondering whether or not there's any relationship between the intensity certain forms of exercise make them very hungry. I'm wondering whether
there's any relationship between the intensity or type of exercise and the hunger stimulus.
Now I don't have this problem because basically everything makes me hungry. And yet I'm also
okay fasting for part of the day. I'm one of those pseudo intermittent fasters. Talk about
what I mean by that. I just have an e between 11 a.m. and 8 p.m. naturally.
I'm not religious about it, but I don't do it for any other reason, except that that
tends to be when I'm hungry and exercise outside of that in the morning, typically.
In any case, is there a way that people can determine what type of exercise might be better or worse
for them based on its appetite, stimulating or inhibiting effects?
Because I also hear that some people will go for a long run and then they are going to
go not hungry for several hours afterwards.
Does that have anything to do with which fuels are being utilized during different forms
of exercise?
That's actually a really good question.
I don't know the mechanisms that could explain that answer.
What I can tell you is you hear the same comment for physical activity.
In other words, people say, man, if I do this type of training, then I just am exhausted
and I lay around the rest of the day.
So my total cloric expenditure is actually compromised as an aggregate because I'm down.
The data would suggest in general that doesn't happen. So most of the time we don't
see a reduction in physical activity with either high intensity or steady state training. In fact, you
generally see equal if not increased what's called need. So it's the non-exercising part of your day
in addition to the basal metabolic rate. So physical activity wise, you don't send to be
problem. Now hunger is a little bit of a different thing. The answer here is, I don't think we have time to actually
do justice on this. So perhaps best to not get into this one.
Yeah, why don't we punt this down the road to our discussion about nutrition specifically
and we've backed it. So we'll ear market for that. Meanwhile, it sounds like if one is
thinking purely in terms of burning calories,
and getting the health benefits of exercise to create a caloric deficit, to create fat loss,
it doesn't matter whether or not they burn those calories using a form of exercise that relies
predominantly on carbohydrate, fat, or protein. Correct. It's not that it doesn't matter. It's that
either one will work, because when we say things like not that it doesn't matter. It's that either one will work.
Because when we say things like that, it doesn't mean they're actually identical.
There are some slight differences and maybe those differences are important for some people
and not others.
I'd say it's either one is a viable strategy.
Great.
What about protein as a fuel?
As an actual fuel.
So let me give you an analogy.
Imagine that you were with me a few weeks ago in Southern Montana and we were out in the
wilderness for a week, okay, and it's cold out there and you needed to make a fire.
And if I said, look, you can pick any of these things.
There's some wood over there.
We brought some newspaper and then we brought a match and we needed to create a fire.
And we're going to use that fire to energy and heat up.
Okay, I said great.
The very first place you would probably start
to make that fire is the match.
You like the match and any match,
hey, it's gonna light immediately,
but it's probably gonna last five to 20 seconds.
I don't know before it burns out.
That's phosphocreating.
Real fast, real burns out.
If you were smart, you would take that
match and then light the newspaper on fire, right? Now, if you were to burn a
whole newspaper, it is more energy than you get to the match, but you still, you
know, I don't know what's going to take a few minutes, some number of minutes
before an entire newspaper burns up. I don't know, right? Depends on then.
Yeah, which type of newspaper is I guess, right? Amazing.
That's carbohydrate.
Right.
If you were really smart, you would use that to then light a piece of wood on fire.
And a wood, if you've been in the wilderness, it could last hours, days.
It's really quite unlimited.
Your phosphocreatine storage is very limited, small.
Glikogen is a lot higher because you can store it in muscle, you can store it in other places.
So you have more, but not a lot.
Fat is unlimited.
The average person, if you're around,
to say, 70 kilos, up 170 pounds or so,
and you're moderately lean, maybe 15% body fat,
nothing crazy.
You probably have enough stored fat
to create enough energy to survive
for more than 30 days.
Right.
This would literally be if you ingested zero calories, you have a
enough fuel in your stored fat to keep you alive for certainly 30 days.
You wouldn't feel good and all those things.
But energetically, basically fat will never, ever be your limiting factor
performance.
So when we start talking about,
well, what limits my performance in these areas,
you can just wipe fat off the list.
It will never be your limiting factor
to any type of endurance performance.
You simply have way too much.
The only problem with fat is it's just too slow.
I've got to mobilize it.
I've got to get in the blood, move it, that whole thing.
Too slow. So if I want to go faster, I will never be able to fully utilize fat, which is why we talked about earlier.
You'll never see a situation in which somebody is a hundred percent burning fat as a fuel and no percent carbohydrate.
It's always going to be too slow. Highest you'll get maybe seventy-so percent.
Protein in this equation is none of that. Now you may notice
how do you make paper? What's five years you combined with water that you get pressed,
they get compressed, yeah. Yeah, it's made from wood. How do you make a match? It's made from wood.
What's carbohydrate, a chain of carbon?
What's fat, a chain of carbon?
These are similar molecules, right?
They're meant to give you pros and cons.
It's very difficult to just light a log on fire
without a lot of work you have to burn, burn, burn, burn, burn.
So these are complementary systems
that are really close to the same thing.
Protein is none of those things.
Protein is more like a piece of metal. So
if you were out in the woods with me and we were trying to make a fire and you're like,
hey, look, I found some old real road over there. Let's throw that on there. I would probably
look at you like you're raising up technically. Can you melt metal? Sure, but you're going
to burn a lot of energy to try to get a little bit back out of the metal. And now you've also cost yourself a very, very valuable structure.
So protein is a fuel source for exercise or metabolism.
It's just an incredibly poor choice.
Your body will do it, again, maybe 5 to 10%.
But you now you're burning a very valuable supply in a situation in which you don't know
where there's ever going to be anymore.
Remember protein is fairly transient.
It's and you're not very good at storing it. in which you don't know where there's ever gonna be anymore. Remember, protein is fairly transient.
It's, and you're not very good at storing it.
You can store a ton of carbohydrate
and an unlimited, literally, amount of fat.
So, you just really need to disregard thinking about protein
as a fuel source.
Your body does not want to do it.
You're not good at it.
You can go through a process of gluconeogenesis
from protein, make glucose from it, it's just very
poor. You're not going to get much out of the exchange and you've burned your supply of metal,
which is going to be very difficult. It's a very high commodity in the woods or the wilderness
to have something like metal. For people that consume very low carbohydrate or zero carbohydrate diets, are they pulling more energy from muscle,
so which I imagine is a conversion of amino acids
into ready carbon chains?
Yeah, I mean, in this particular case,
once you've reached a certain level of adaptation,
you've just gotten extremely good at generating glucose
from other fashions, right?
So you can bias heavily towards fat adaptation.
The downside is, and we've seen this born in literature,
you're going to perform slower.
So if you don't care about maximizing performance,
especially over something where it is a maximal effort
for a few minutes or something,
then maybe you're not concerned.
And that's absolutely great, especially
for people just don't exercise.
Then hey, geez, very little concern here.
But if you're interested in your performance
and you're wondering why you're just like slugging it down,
well, what you've done is you've down-regulated the ability,
literally the enzymes responsible
for that entire anaerobic glycolysis portion,
they get down-regulated,
which means there's not as much around anymore.
And so you get really bad and slow at using carbidaries
as a fuel source.
So is it very poor strategy for people on an anaerobic based sport or who like that type
of activity?
Can if you don't care, no problem.
If you don't actually, as at all, then you really have no problem there, which is actually
why a high fat low carbohydrate nutrition strategy for people who don't do much physical
activity is probably like very effective.
It is a really good strategy for weight management,
for energy stabilization throughout the day,
and the research would very much support that.
In my observation, I would agree.
I've tried low carbohydrate diets of severely limiting
or completely eliminating carbohydrate.
And after about two or three days, I feel pretty lousy,
but mostly because I want to train
very intensely in the gym.
In addition to doing longer runs, I tend to do all of those things across the week.
But I've also observed, and in fact, know several people that love the very low carbohydrate
aka ketogenic type diet.
They're not doing ketogenic diets for mental health reasons per say, but
indeed those people tend to do very limited exercise, or they tend to do a lot of long endurance,
but low intensity long endurance. These are the, I walk to get my exercise types, and they do
indeed walk a lot, and some of them manage to control their weight very readily, and like that
diet for that reason, when we had Lane Norton on the podcast,
he pointed out quite aptly that in order to lose weight,
you have to restrict something either.
Of course.
Time or macro nutrients, et cetera,
to arrive at that subchloric threshold.
Get below the sub maintenance threshold.
I guess one of the things I wanna point out is
this should be used as again, not
a, this is better or worse.
This is this, you now have a ton of options.
So whatever personal preference, other factors, you get to craft this strategy of performance,
aesthetics and health based on your personal preferences.
At this point, I'd like to go back to our classic list of nine adaptations that exercise can induce.
The first four, two speed,
three power, which is speed times force, four strength, and five hypertrophy.
Today we're talking about the remaining adaptations on that list, starting with muscular endurance
followed by anaerobic capacity, followed by maximal aerobic output and finishing at
number nine with long duration exercise.
So, if we could start with muscular endurance, this would be number six on the list of nine adaptations, muscular endurance.
How do I build muscular endurance? Why should I build muscular endurance? And just to remind me, what
fuel sources are predominating when I'm training for muscular endurance?
Great. So remember, muscular endurance is something that's going to be generally in a local
muscle. It is not a cardiovascular or systemic issue. And it tends to be something in the neighborhood of say five to maybe even up to 50 repetitions.
So this is the classic example we'll give you here
is how many pushups can you do in a row?
Most people are gonna land somewhere in that range,
I just said, how many situps can you do in a minute?
How many pull-ups?
How long can you hang on a bar as a dead hang?
Things like that, that's muscular endurance.
Muscular endurance is not a mild run or a marathoner day like that.
So how long can I stand without breaking posture?
This is muskier endurance.
A plank, a wall sit.
Great, yes.
Love all these things, okay?
Now, the reason I took you on that big long metabolism journey is so I could help you understand exactly how to train this
factor or any of these factors with a more comprehensive understanding what's happening.
Meaning, thinking back to the metabolism, if I'm going to ask my triceps to do 50 push-ups
in a row, what's going to be my limiting factor?
Am I going to run out of fat, no chance?
Am I going to run out of fat? No chance. Am I going to run out of glycogen?
No chance.
That's way too few of repetitions.
You have a lot left there.
So what's going to be the thing that stops me
from getting 51 repetitions?
Either you're going to have too high of a pH rise,
so too much acid build up,
or you're going to have a problem clearing the waste.
So really this is two factors dealing with acid build up and getting acid out of the muscle
tissue and endocirculation because you have plenty of ability to handle that small amount
of acid build up in your entire body.
It's just you can't handle it in that tiny spot.
Now I picked the tricep for a very specific reason.
You're gonna deal with more pain
when you use a large muscle group like your quads
or your glutes, then you are with a small muscle group.
For example, nobody ever threw up after arm day.
But a lot of people throw up after leg day.
Why is that?
Look at the total amount of waste
that you're dumping into your system when you have quadrupled or 10X the muscle size.
Small muscle groups are only really going to be challenged in that local area. Large ones will dump so much waste into the system that you'll want to avoid that as quickly as possible.
And that's one of the reasons why you throw up after hard exercise. Great. So the reason I'm laughing because I don't think I've ever thrown
up from a weight training session and so it's making me wonder if I've ever trained that
hard. I've received or obtained the progress that I want to do generally over time, not
every week, every workout every month, but certainly over the 30 plus years that I've been weight training, I've achieved
the results I've won. I have, however, vomited after a long run when I didn't hydrate well.
Oh, sure. You wore if I drank too much water. Sure. Oh, sure. Too much water. Yeah, you'll
get that out quick. Right. I just want to be clear because I think some people are getting the
picture that if they're not vomiting, get them after their leg workout, that they're not training
according to your standards.
Again, by the way, Dr. Andy Galpin runs experiments
in his lab, he's recruiting subjects.
That's how I'm doing.
I also noticed my graduate students.
That's right.
In any event, sorry to interrupt,
but I felt it was a necessary interruption.
So muscular endurance, there's plenty of fuel.
Plenty of fuel, you manage acid build up, and you also need to get that's plenty of fuel. Plenty of fuel you manage acid build up
and you also need to get that fuel out of you.
That's gonna be a capitalization issue.
So the way that we can think about this
is capillaries surround your muscle
and the whole point of them is so that blood
can come into them.
They hit this capitalization.
That actually slows the diffusion rate of blood down
and so you can exchange nutrients
in and get waste products out and then we get things back in circulation. So the more of those you
have the better you are at dispersing any of these waste products build up whether it's CO2 or
the acid. So the adaptation you're looking for here is an increase in capitalization potentially
a slight increase in mitochondria but the time is too fast.
So we're going to be able to do these 50 repetitions in, say, under a minute or something like that.
So getting the mobilization into the mitochondria, getting fuel that way too slow.
It's not really going to get our performance here. So what are strategies to increase acid
buffering ability and then capitalization.
So on the capitalization side, you simply need to train at that ability.
So you go close to failure and practice that often.
That alone will increase blood flow to that local area, which will take you through
your process of increasing capitalization.
Easy peasy, specificity.
Right, so I have to do that.
Just to briefly interrupt, I find it remarkable, although not surprising, giving how amazing
the human body is, that simply by doing some movement repeat like a wall sit or a push-ups
or dips for that matter repeatedly, over and over and over until you reach that failure
point or that quaking point in the case of a wall set,
that provides a stimulus for more capillaries
to be built into the system.
Literally, the production or the trafficking
of endothelial cells, which make up the capillaries
and allow basically more little pipes
to feed the system with oxygen and remove waste products.
It's like irrigation, right? Imagine you had a giant field and you had two big pipes to feed the system with oxygen and remove waste products.
It's like irrigation, right?
Imagine you had a giant field and you had two big pipes running down the outside.
Well, in fact, if you want to make sure water gets eaten in the dispersed growth of the
entire field, you'll have a bunch of offshooting little pipes.
And the more those you have, the more coverage you get.
Do we know what the specific signal is that says, Hey, I failed at this.
We need more capillaries.
I actually don't know what that is.
I could speculate it's a combination of acidity
as well as carbon dioxide and probably some nitric oxide
stuff happening there, but I actually don't know.
I'm guessing nobody knows for sure
because we still don't know, for instance,
what the exact signal is for hypertrophy.
It's kind of an amazing situation.
We know the requirements for getting the result we want, but we still don't know what the
specific signal is.
In any event, what I'm hearing is building more capillaries is great for enhancing muscular
endurance.
And the way to get more capillaries into those muscles is to train for muscular endurance
by getting close to failure or to some point
where you simply can't continue for whatever reason.
Could you give us an example of what a reasonable training
protocol might be in terms of the classic galpin list
now exercise choice, maybe a few options, order,
volume and frequency.
What should we be doing?
How often should we be doing it?
And for instance, I do wall sits to failure
then push-ups to failure.
Given that this is a local process,
I'm guessing that if I do push-ups to failure,
I'm not gonna increase the number of capillaries
in my legs very much.
Correct.
So you nailed it.
Exercise choice is high precision here.
So pick the muscle group
and the exact sequencing and movement pattern you want. High precision. This is the thing.
If you want to get better at applying cold to plank, you want to do more push-ups, two more push-ups.
You can do some other stuff that's complimentary, but really this is a high precision game. Do the
exact same thing for exercise choice. Very simple there. Okay.
In terms of exercise order, I suppose this dovetails with volume.
Yeah.
Can I combine training, let's say, wall sits for my quads and nearby muscle groups and
then do pushups to failure and then also do some sort of pulling exercise to failure?
Yeah, absolutely.
Again, pick the exercises you want,
the movement patterns you want to do,
and do them.
The order almost doesn't matter with the one caveat,
with larger muscle groups, particularly again,
multiple leg activities.
That will induce a small amount of systemic fatigue.
And so if you, I guess, theoretically,
wanted to maximize your push-up number,
and you did a whole bunch of, say, split squats and you just did those and you, you, you know, did lunges
for a mile or something like that, you might actually slightly compromise, you might not,
but you might slightly compromise your ability to do as many pull-ups in a row or hold a bent
over row or something like that.
So if you really cared about that level, then you maybe want to do the thing that's most
important first. In general, my recommendation though
is to do the bigger muscle group first. How many sets and how often should one perform training
for Musco endurance and when? Now, the lovely part here is we've moved down the spectrum past
hypertrophy. You don't need a lot of load here. In fact, the load only needs to be at
or slightly above what you wanna move.
So if you wanna get better at moving 50% of your one
or max, you don't really need to train much more than 50,
maybe 55 or 60% of your one or max.
Because if you go higher than that,
the repetition counts going to fall.
And you're no longer going to be training muscle endurance.
So you just need to stay right around that number that you want to work on.
So again, if the target is doing more pull-ups and assuming that you have this strength to
do it, and you check that box, you simply need to practice the repetition range that you
want to be in.
That's all it takes.
You can repeat that a number of times, but because
remember, the volume is fairly low. The load is very, very low. You can actually repeat
these quite frequently. So you won't get extremely sore from Musco endurance relative to traditional
hypertrophy straning because the load is very, very light. So you can do these more frequently
if you would like. More frequently such
as you could do a three or four times a week easy. If you would like, you don't necessarily
need to. Three days a week per muscle group is probably fine here. If you wanted to do more
sets on a given day and do less days, that would be fine. So if you wanted to do two days
a week and you say wanted to do, let's say you could do 25 pushups and the goal is to get to 30 pushups, just as an example, you might say,
okay, I'm going to do sets of 17 and I'm going to do three sets of that.
I'm going to do that three days a week.
That's going to build up quite a bit or you could say, look, I'm going to do a set basically
to failure.
I'm going to recover and do one or two sets at say 80% and I'll do that twice a week.
That's going to push the pace pretty well.
You're going to have a lot of gains from that.
And again, this is not about hypertrophy.
This is about muscular endurance.
Correct.
So I do want to emphasize, and again, please correct me if I'm talking out of line here.
I do want to emphasize that? Because we mentioned pull ups.
If you can't get 25 pull ups,
then and you're doing 10,
you're training for high-perchery,
you're not training for muscular endurance per se.
Remember, there's a big cross over here.
So anytime we're talking past like 15 reps,
we're technically in high-perchery and muscular endurance.
Got it. So here's the common mistake.
I don't wanna get bulky.
So I'm gonna go lighter and do more reps.
And then people grow.
And then you landed still right
in the middle of hypertrophy range.
So like for people who are like,
oh my gosh, like every time I lift weights,
I blow up, I go lighter, I do more reps.
And I, you're still right in the hypertrophy zone.
They'd actually be much better off training very, very heavy in the one to three rep range.
They get really strong and they wouldn't grow much.
Exactly.
So, tell me if this is a reasonable protocol for what I'm going to call the typical person.
In my mind, the typical person, somebody who hopefully is doing resistance training,
hitting that 10 sets per muscle group, per week, minimum to maintain or build strength
and hypertrophy.
But it's also doing some long duration training
that we'll talk about in a little bit,
maybe throwing in high intensity workout here or there,
some sprints, maybe some plymatrix, some skill-based training,
and doing a bunch of different things
to be what I would call all around fit.
They're not training for any specific event
or trying to maximize any one of the nine adaptations
to the exclusion of the others.
That person decide, okay, after they do their longer run,
they're gonna do a plank to max duration.
They're gonna do a wall sit to max duration
and they do pushups to max duration.
And then also do that same workout
before they do their high-intensity interval training,
some other point during the week.
And then maybe even do it again
on their so-called rest day,
just a real quick five minutes of
sure. And in doing so, build more capillaries into the relevant muscle groups
and build their muscular endurance. Yep. Without eating into their overall
recovery too much. Too much. Yeah. So again, the nice part about this is they
don't hammer you too much. You're not going to get tremendously sore if you keep
the load light. The only switch I would make there is I would probably do them
after your interval rather than before. So you can make if you keep the load light. The only switch I would make there is I would probably do them after your interval
rather than before,
so you can make sure you keep quality there
and you're not compromised by a local muscular endurance
when you're actually trying to get a more systemic fatigue
with something like a higher intensity interval training.
So that would work fantastic.
The only other variable we have in here is progression.
And this is very simple.
Try to add a rep or two per week.
That's really all you have to go after.
So if you're up to 22 this week,
try to hit 23 next week.
Well, for wall sits and planks that would meet at a time.
Time. Yep.
And if you run into a wall there,
just like the same concepts we talked about
with strength at hypertrophy,
back it down to more like in the 80 or 85% range
and accumulate a lot more practice.
That's gonna help a lot with capitalization
as well as acid buffering.
So you're gonna continue to give yourself signals
for up regulation of the processes needed for that
and it's not always pushing you to the end failure.
Just like we don't want to always go to failure with strength.
We don't want to always go to failure
with high intensity andensity minerals either.
Same thing would be happening here.
What about anaerobic capacity?
How should people train for anaerobic capacity?
What exactly are they training for, meaning what is the structural or cellular adaptation
or adaptations that are occurring that allow for increases in anaerobic capacity?
And why are increases in anaerobic capacity good for us even if we're
a quote unquote endurance athlete or we are a recreational exercise or who is not interested
in building more muscle speed or things that I typically associate with anaerobic capacity.
Yeah, so this is really, really fun. Remember anaerobic capacity is a total amount of work you can do for
something like seconds to a few minutes. And this is extremely high levels of fatigue.
The highest you're really going to see, and by fatigue here, I mean acid build up by
products, not fatigue as in like mentally, I don't want to do this anymore. So if we just
think about the energetics for a second, I'm going to do say let's take
a really easy example of people have done that thing where you, you'll go to the track and
you sprint the straightaways and you walk the corners. Remember that sort of thing?
Yeah.
Uh, Tabbata's, 30 on 30 off. Things like this, like this is what we're talking about,
in this kind of anaerobic capacity area. Now,
here's what's going to happen. Is fat going to be your limiting? No, we already made that clear,
right? What about carbohydrates? Well, if it's a single bowed or a two or three bowts, probably not.
But if you're doing this for a long time, say you're going to go 30 on 30 off for 20 rounds.
You may actually
start reaching a point of running out of my Muslim vikagen. In any of those cases though,
you're going to be running into an acid problem. If you were to continue to do this multiple
repetitions in addition to running low on Muslim vikagen, you're also going to start
running into oxygen transportation problems.
Because you're building up a lot of bioproducts, you've got to continue.
You will actually cruise into aerobic glycolysis.
This is exactly why the community that I have worked a lot with, professional fighters,
very high level boxers, world champions, UFC fighters.
It is a five minute round that you're going to do five times.
This is for World Championship 5.
You get one minute break in between.
So imagine going like 30 on 30 off for five minutes, getting a one minute break and doing
that five times.
Even though the individual ballots are 30 seconds long, the entire thing lasts so long.
It is primarily a robot.
You have to have both capacities.
You've got to get really high anaerobic.
You also have to have a lot of aerobic going on.
You're going to start running into limitations
because of heart rate, stroke volume,
and then even potentially ventilation.
The need for oxygen to be able to come in
and clear the carbon dioxide
totally out of the system becomes a problem
because not only are you having so much build up
for such a long time, you're also using multiple muscle groups. So now this is a very important distinction.
Muscle endurance tends to be localized. Now this is not right. If you're doing these
intervals, you're on an assault bike, you're sprinting up a hill, you're grappling with
somebody. You have a lot of muscles being involved, which means all of that waste is being
dumped into the central part. You have to clear it and I'm by clear it, I now mean not out of the muscle, I mean out
of the body.
So your ability to bring in and utilize oxygen is going to be a major limitation to your
ability to handle this stuff.
So what do you do?
Well, specificity wins.
Practice the exact thing you're talking about.
So if you want to get better at sprinting this right away and walk in the corners, do that.
You can't always do it though.
You're gonna run into limitations.
So this is when backing off to a lower intensity
is gonna give you a lot of benefits.
We know very clearly if you want to improve
cardiovascular fitness, high intensity,
moderate intensity and low intensity are effective.
And you actually probably want to do a little bit of all of them.
This is why none of our fighters would ever just do high intensity training.
There's going to be some moderate.
We tend to call this like cardiac output training.
You can think of this as like anywhere between zone two to zone four.
If you like zones, I don't use them personally.
So I'm just going to intentionally interrupt you because this issue of zones has come up
a few times and I want to make sure everybody's on the same page. You also mentioned that you
don't necessarily favor the zone nomenclature, but for those not familiar, zone one, two, three,
four, all the way up to five is a, kind of, back of the Yomvalope type
verbiage for some people and is more precisely followed by, for other people, meaning for
me, zone one is simply walking, easy walking.
Zone two would be for anybody the pace or intensity of exercise that one could perform
while still maintaining a conversation, but just barely. Meaning if you were to
push any harder, then it would be difficult to hold that conversation. Then you'd
be in zone three, and then zone three, four, five, as I understand them, are a
little bit vague, but maybe you could give us a sense of the breathing patterns
associated with each of the zones,
so that people could map to those when we discuss zone 1 through 5.
And as I say all this, I certainly tip my hat
to all of those people out there who like to measure percent
of maximum heart rate.
They like to use heart rate monitors.
They're using any number of different devices.
I sometimes use those devices, but in general,
I tend not to and I use my breathing
as a rough guide of which zone I'm in.
So before we go back to specific protocols
for anaerobic capacity, tell me how you think
about zone one through five and how people might be able to assess
whether or not they are in zone one, two, three, or four or five.
Great.
Zone five is that absolute top thing.
We can flag ourselves there.
I like how you flag one and two.
The distinction between three, four, and five, I'm less concerned with either.
We will do some heart rate stuff, but not to identify what zone run. The fact is the distinction between those zones is basically just made up, right?
But not that it's fake, but there's no like rationale there.
It's a little bit like perceived effort when we're lifting.
You know, how are you at 100% output or 70% you know when you're at zero and you know
when you're at 100 in that moment, but the difference between 60 and 70 is
Anybody's guess totally so we use or the relevance right? So why does it matter from a 60 or 70?
Is there actually a difference? There's not right? So it doesn't really matter in that regard
If you're very highly trained particularly cyclist things like that then and you can control a lot of circumstances
Those things start to make a lot more sense
But when you're in an open environment like the athletes I deal with, it's just not going
to matter that much.
So the way that I approach this is, and I will use this word intentionally, stolen directly
from Brian McKenzie and his company, Shift Adapt.
They use what's called a gear system and I absolutely love it.
It's what we've been using for a long time.
So with Brian with your permission, I'm gonna take it right now. Thank you, Brian. He gave me the permission to.
Thank you, Brian. Brian's a good friend of of of ours. And I do think the the breathing gear system is a
terrific way to think about the zones and to get a good sense of what zone one happens to be. Yeah, great.
So the first gear is your ability to simply breathe in and out through your
nose at a set cadence. So basically, regardless of how hard you're working, can you restrict
your breathing to like a two to three second inhale and then a two to three second exhale.
And this is really clever actually because a lot of folks will jump immediately into
an over breathing
strategy. It's meant to be ventilating more than you need, which actually sends
that RER up higher than it needs to be, which kicks you higher into carbohydrate
utilization. If you're supposed to be in quote unquote zone one, you're trying to
be efficient, not fast. So using more carbohydrates than you need is not
beneficial here. You're walking
for the day. You're out on a longer hike. You're enjoying the day. You shouldn't be trying to ramp
up carbohydrate metabolism. It should be efficient. And so this would be getting into an argument with
somebody while on a long walk. You feel exhausted afterwards. You're an over breathing. Yeah, totally.
Right. So you should be able to breathe at a specific cadence
and generally people are doing that more frequently
than they need.
Right.
Zone two, rather gear two is inhaling and exhaling at whatever rate
you need it to be, but still nasal only.
So it is a force.
Right.
Whatever you need to do,
but your mouth is closing entire time.
You shift it higher up, you're burning more and more
carbohydrate as a fuel source,
but you're still able to control that
and restrict it to nasal breathing.
Now, gear three and four, which is our final ones,
there's no gear five.
Gear three and four is like a subtle distinction.
I actually don't even care about the difference there.
I basically use gear one, two 2 and then F's 4.
But you're basically talking about either a nose
to mouth strategy or a straight up mouth mouth, right?
So breathing in through the nose, out through the mouth.
If you can control it that way, you can do the opposite,
actually, right?
Can you breathe in and out through your nose?
But the classic one people do is into the nose
out there in the mouth.
Again, I really don't even care about this distinction.
I basically jump from two to four.
A Brian may do it differently, I don't actually know.
Four is just mouth, mouth, right?
And this is the case in most sporting applications.
You're gonna be breathing because the nose is restricted,
there's only so much space.
And as we talked about earlier, the consequences
of not having enough oxygen in or CO2 exhalation,
if you're restricting that, this is going to be problematic.
So in your actual competition, please go to the mouth if you need to, right?
We've practiced a lot trying to stay nasal only for as long as possible, but that's going
to eventually happen.
When you're doing your high intensity intervals and you're really going as hard as you can,
you're going to have to go to your mouth unless you're an absolute free
kazoid and you can say in your nose, but that's not going to happen, right? Most people can't get
past, say, 70 or 80 percent while breathing through your nose. I know some people can get higher,
but that's the general distinction. So we pay much more attention to those particular gears
than we do heart rate zones. And zone five would be just pure mouth breathing all out.
Yeah, again, the gear system's just one to four.
There's no fifth gear.
Got it.
So the gear four would again be mouth mouth breathing as much
in as you can, breathing as much as you can out.
Got it.
And I appreciate your description of the gear system and how it
roughly relates to the zones we've been talking about.
Also, in reminded, if anyone wants to experience the relationship between
breathing and the offloading of carbon dioxide and your ability to
exert effort in anything, a game that a friend of mine sometimes
likes to play when we walk or jog and talk is he'll say, let's
just hold our breath now until we hit that piling or that
lifeguard stand on the beach. And within seconds, you actually can start to panic.
Absolutely.
Also, it becomes very hard to coordinate your action after a little while.
Again, be really careful with this, but it will teach you in a moment in a very real
world way how important it is to be able to offload carbon dioxide because you're probably
not running out of oxygen
at those lower intensities.
You're simply building up carbon dioxide
and that gas brief like this screaming
to go off and you're actively suppressing it.
Yeah, so the interesting test here is your CO2 tolerance.
On Ryan's website, you can go directly there.
You can, there's a video to how to run this test
and then you can put in your numbers
and it'll tell you sort of exactly what to do
as a result of it.
But the CO2 tolerance test is a test of exactly what you just mentioned.
So you should be fairly tolerant, in other words non-reactive,
you can be responsive, but non-reactive, two elevations in CO2.
So you should see them and feel them, but you should be choosing how you respond rather than an reaction.
There are interesting data looking at things like out of the
blue panic attacks.
You can actually notice those in blood,
the arises in CO2 up to 45 minutes prior to the event
to happening.
So there are signals happening in your body that you may be
sensitive or not sensitive to.
The more in tune you can get with that,
the better your life is going to be.
And even if we're specifically just talking about exercise performance.
So it's okay for CO2 to rise. It's going to rise. It's a byproduct of anaerobic,
anaerobic metabolism. It's a byproduct of carbohydrate and fat metabolism as we've established.
It's going to get there. You're going to feel that. However, if you immediately go into a panic because of a small increase in CO2, this is
a problem.
So we're turning to anaerobic capacity.
This morning we were training not together.
I couldn't keep up with your workout.
But in the same general space and I did my once a week maximum heart rate, one minute
sprint on the assault bike.
Sometimes I'll do more minutes,
meaning I will do one minute than take some rest
and do another minute after some rest.
But I decided to do that one minute with you there
so I could learn from you.
And indeed, I have to assume that that was largely
within the anaerobic capacity realm.
The first 30 seconds or so were manageable,
we gain more and more painful.
There was a quit signal going off in my head.
You said there's real magic that occurs around second 40
and indeed somewhere around second 40,
for whatever reason, it seemed easier.
But at the one minute mark, I was happy to stop
because I was really at least what fell to me,
100% output.
Is that a good protocol for building up anaerobic capacity,
keeping in mind what you said before,
which is that specificity or precision as you raised it,
is important.
That is, if I want to train anaerobic capacity
for sprinting, I probably should have been sprinting.
Cycling, I was only a salt bike, and so on.
How many of those one minute all out sprints or 30 seconds all out sprints on the bike could
and should one perform per workout and per week.
So marching through exercise choice.
Yep, let's do it.
Order volume, frequency, and progression.
Yep.
Choice of exercises trained for what you want to
improve, is that right? Not necessarily. So in this particular case, if you have a
specific goal, yes, of course, do it. Exercise choice, a couple of things you want to look for.
You want to pick something that you feel extremely confident in the movement with.
Because you're going to forget your brain very quickly here because you're going to go into our pain cave.
Okay, so if you're not comfortable running, don't go run here.
You're never going to get the spot we need to get to it.
If you're not comfortable or if every time you go on a row or you're low back hurts the
next day, don't do it.
If you're not comfortable using kettlebell swing, it's like you get the point.
Don't do an exercise, you're not comfortable using kettlebell swing, it's like, you get the point. Don't do an exercise you're not comfortable with.
You also secondarily wanna be careful,
cautious of heavy eccentric loads.
Because you're gonna be doing a lot of repetitions
at a high intensity.
So this is where I love an assault bike.
This is where a roar is great.
Swimming is amazing.
Running uphill, generally more favorable
than running on normal ground,
especially if you're not runner.
Don't run downhill.
That's a lot of eccentric load.
I don't love things like box jumps here, right?
Because again, a lot of eccentric loading, if suppose you can jump up one of the box step
down, but now you're, again, you're too many things going through your mind.
I don't want to slip and fall.
I want to smash my shin on the box.
What happens if I'm too many variables?
Pick something that is safer where you can
really focus on your breathing and your posture and the performance. All right, so that's
exercise choice. And then within that, if there's some specific thing you want to get
better at, go ahead, do it.
Okay. How many different movements, meaning should I do the assault bike and then some form of safe, executable overhead pressing.
It's a little harder to imagine interrobic capacity
for the upper body unless you have access to a skier
or one of these, what are those things called?
The climber machines.
Yeah, the Versa climber.
The Versa climber, that's the one, the Versa climber.
You can tell how often I do that one.
Yeah, it's a great ex. That's a great exercise.
This is a great piece of exercise equipment.
Yeah, so we're thinking how many exercises
and in what order is it going to be two or three exercises
since you're involving a lot of muscle groups, typically?
Yeah, that's a really distinction.
Generally, these are going to be total body movements.
So you can do something like a skier egg
if you want to really isolate your upper body. Great, love that. You can do lower body isolation like cycling.
All right, where your upper body is not involved. You can use weights here. You can do some
barbell movements and stuff like that. They're just not my favorite choices for most people.
Too many complexity things going on. So I generally am going to pick total body movements, pushing a sled,
dragging a sled, sprinting uphill,
swamming, these things like that are gonna be good.
I'm seeing now why the assault bike
is such a powerful tool
because you're using your arms
with some degree of resistance,
but not a lot of eccentric load,
plus legs, some resistance, not a lot of eccentric load,
and yet one can go, quote unquote,
all out for 30 to 60 seconds.
Yep.
And the consequences of a technical breakdown are minimal.
It's more like you're going to actually have a worse performance rather than an injury
rate.
So they're just a wonderful invention because of that where other things, the consequences,
like say, if you're going to be doing a barbell or kettlebell activity, the consequences
of making a technical mistake, you might actually get an acute injury right there. So they're
just a little bit higher in the risk of scale. How many sets or sometimes referred to as
repeats? Yep. So how many 30 to 60 second all out sprints? Again, doesn't have to be running
sprinting, but all out effort would be the better way to phrase it. Should I perform, let's say per week and then decide whether or not we can divide those
up across multiple workouts or whether or not it's better to do them in the same workout.
Yeah.
If you're staying with the same exercise for all of your workouts, that's a little bit
different answer than if you're modifying them.
So say you're going to do this three times a week and you're going to do an air bike one
day, you're going to do some hill sprints another day and then you're going to do this three times a week and you're going to do an air bike one day you're going to do some hill sprints another day and you can do some swimming another day. For a sake of example
I'm going to say
same movement
because I think most people are going to be most comfortable with one or two
types of movements, yeah, unless they are
Really coordinated or an excellent athlete. I think most people can probably find a hill that they could run up and an air dine
or a salt bike, a rower, things that sort.
Yep.
You're gonna have a pro and a con here.
So the pro of doing less sets is you can actually train
much closer to truly 100%.
The downside is volumes low.
Okay, so a major mistake people make here is they'll
do something like, I'll do 20 seconds on, 10 seconds off, and I'll do that for 40 rounds.
You're not really actually going that hard in those 20 seconds. So a key, in fact, if
you look at the literature and all the buzz and all the positive benefits of high intents
in your training, that assumes you are actually hitting
very close to 100%. If you're sliding down into, like, again, moderate training stuff,
you start to actually be in a spot where you're not getting the total high end stuff,
but you're not doing it long enough to get the low end stuff either. And so you end up in this
like, you burn some calories, you probably still enhanced myocondropylgenesis and a little bit of capitalization, but you didn't really justify only
doing three rounds. That's where the problem comes in. So in terms of a couple of protocols,
I'll give you a how many sets per week. It's really hard to give a number unlike the
strength training stuff where it was easy to kind of land some stuff on. A typical thing
you'll see is like a minimum of those
tends to be something like four rounds
per day, three times per week.
Wow, that's a lot.
So my once a week, all out effort of sprinting on the
assault bike, the so-called air-dine bike,
four 60 seconds, one to three rounds of that
might be doing something useful for me, for 60 seconds, one to three rounds of that
might be doing something useful for me, but I should probably be doing that two or three times a week.
If you're gonna get to a max heart rate,
I'd generally like to say,
give me a minimum of one day a week, two is better.
Days per week, how many rounds?
Whatever it takes you to get to that maximum heart rate.
Right, so in your case, you did one minute. Okay.
Good.
If you're going to extend past a minute or two, one round might be enough.
So for example, if you want to just do something where I'm going to run a mile as fast as I
can, that's all you need to do for the day.
You don't need to do multiple.
You can do mile repeats if you'd like, but that is really, really challenging.
I know we've extended the time duration here,
but I wanted to go there to show you.
The time domain matters here.
If you're doing something like a 22nd burst,
you're going to need more rounds.
If you're doing something longer like multiple minutes,
you don't need as many rounds to get there.
So in addition, if you're really reaching past
this 90 seconds of hell window, it's just going to do a lot
more damage to the system.
Not damage is in bad, but it's in there's a lot to recover here.
So we need more recovery time from that.
A 22nd burst doesn't really challenge you.
The challenge is in that 20th second ship, but you'll be recovered and fine.
A three minute thing is going
to hurt and it's going to hurt for many, many, many minutes after that. And you're going to still see
maybe some performance documents the next day depending on what your recovery stuff looks like.
So a couple of things to play with would be something like this. If you want to try like a classic
30 seconds on, 30 seconds off protocol, The literature will show like a minimum of four rounds
of that probably three days a week.
So 30 seconds all out, 30 seconds rest is one round.
Repeat that four times, at least once a week.
At least two would be better.
Great, right?
If you wanna go something a lot longer than that,
you might be able to get away with one.
But generally two days a week of this is better.
If you start actually pushing past
like three to four days a week up to five or six,
you may actually be causing some problems.
There's just a little bit of excess fatigue
that's gonna happen there that you might be wanna stay away from.
In fact, you can see a lot of endocrinological problems
and some other sleep issues
and some other things to kick in.
And we'll talk about more of those things as later.
But that's the number to get with.
If you want to try something more like a 20 second burst, I actually would recommend
giving yourself more rest.
So you can actually do a higher rest than work ratio.
Most people tend to think of this as doing like one to one, 20 seconds on, 20 seconds off,
or lower.
I love doing like 20 seconds on 40 seconds off. The quality of that 20 seconds becomes extraordinarily high.
And it's also possible to now get like six to eight rounds.
So as I'm hearing this, I'm going to wager an offer to you.
And if you say okay, then to those listening.
Based on what you're telling me about the relationship between intensity and quality
and the number of things what you're telling me about the relationship
between intensity and quality and the need
for sufficient duration of this anaerobic work,
how is five to six minutes per week of all-out work?
That's pretty good.
So what that means for me is I would do three all out one minute sprints on
one workout separated by a minute or two. Maybe more. And I would do that two or three times
per week just trying to hit that five or six minute per week threshold.
Yep. Actually, I think one of the Marty Gabala is the scientist, a Canadian guy who's done
a lot of the research on high intensity animal stuff, right?
And I think the number he actually threw out there in some of his original research was
comparing six total minutes of work to upwards of like 180 minutes of work throughout the entire week. And one of the
classic studies was looking at VO2 max improvements. And he saw equal, if not greater, improvements
to VO2 max with that. So I think actually the name of his book might be like the six-minute
workout or something. And so you like may have nailed that directly on the head.
Purely by luck, but actually, by also maybe wrong number, so we should probably fact check that.
Yeah, well, and also by inference from what you were saying, you know also maybe you're on the number of sweet, you're probably fact tech that. Yeah.
Well, and also by inference from what you were saying, you know, if you're going to do this
20 seconds on 40 seconds off, and you're doing more rounds or one minute all out.
So the way I'm going to think about this, if it's okay with you, is for five to six
minutes a week, I am sprinting for my life.
Correct.
But I'm sprinting for my life with good form.
In whatever movement I happen to be doing.
And I can do all of that in one workout, but I'm separating out about of 20 seconds all
the way up to one minute by the necessary rest in order to recover my breathing.
Get back to pure nasal breathing, maybe zone one, zone two.
Totally.
Totally. Totally.
And then hit it again.
If you're going to do the one minute thing like you do, I actually generally encourage
one to three minutes of rest before you do the next round and probably up to four to
six rounds.
That would be your six minute number there.
Now the caveat there is we don't worry about heart rate recovery.
We worry about exactly what you mentioned, which is nasal only recovery.
Once you can get back to that, give yourself another 30 seconds or so,
and then you're ready to go for round two. This is where it gets fun because I can imagine
challenging myself to get on the assault bike for one minute of kind of warm-up, very low intensity
each morning, and then sprint for a minute, and then head off into my daily routine. No. Okay. That,
if you're going to do that, though, you need to give me three minutes of nasal only breathing
before you go back to work.
We need to downgradulate that.
And there are people in my life
that would love for me to engage in more nasal breathing
because it'll have me speaking less.
So no problem.
Chances are I'm going to use the two or three workouts per week
of one minute all out.
Maybe I'll try the shorter protocol.
Can I give you one fun protocol to try here?
Please.
So if you have a, you can use this on any equipment,
but I learned this from another mutual friend, Kenny Ken.
This is a great little, it's a little test,
a little game you can play with yourself.
And the only way to play this game is you're going to lose,
which is really, really lovely.
So you can do this
at any duration of time, but two minutes is a good number. Okay, so you have to do this in someone
where you can know distance. So this could be running, cycling, the air bike is what I use.
The first two minutes, you're going to cover as much distance as you can possibly cover
in two minutes, and you're going to note that.
So let's say you covered 400 meters.
Right?
Okay, great.
You're going to rest for two minutes.
Amazing.
That next round, you're now going to go for distance.
So you're going to cover the exact same amount of distance you covered in round one, which in this example
was 400 meters.
And it doesn't matter how long it takes you.
It may take you two minutes and five seconds.
Two minutes and 10 seconds, because you're a little bit
fatigued from round one.
Round three, you're going to now come back
and do that exact same time domain that you did in round two.
So if it took you two minutes and five seconds in round two, now round three is going to last two minutes and five seconds. And you want to see if you can
cover a greater distance, 405 meters, 410 meters, and then you did in round one. And the beauty of
this little protocol, six minutes total of work, right? But if you slack in one of the rounds,
you just make the next round harder.
Is there any rest between rounds?
Yeah, two minutes.
Always two minutes rest.
You don't have to, but this would be my recommendation.
Kenny Kane came up with this.
I don't know if he came up with it, he taught me.
Well, we both know Kenny and he's an incredibly nice and incredibly skilled trainer.
I'm going to call it the sugar cane.
Yeah, it's so great because it sounds really painful.
And if you go about too hard in Round 1,
you're in such big trouble, Round 2.
But if you go to easy in Round 1,
you're going to get absolutely obliterated in Round 3.
So it's like a wonderful thing,
and you can pick that number as a standardization
and then just try to improve that a little bit for a week.
So progression is the last part of this whole thing
that we haven't got to yet before we move on.
And the way you want to progress all of these things
is you can timestamp, again, how much work you can do,
and then just try to do a slightly higher amount of work,
5% or so every week.
Or you can add a round, which is a really nice way.
So in the research studies that have been done,
they're going to do things like week one, you'll do three rounds.
Week two, you'll do four rounds, three, you'll go five rounds,
you'll add a round and tell you get up to say six or seven or eight rounds
at the end of the protocol.
So that's a really nice way to go about it
or you can cap the rounds and just try to get more work done in that same amount of time. Meaning go more intensely.
Correct. Get further distancing your 30 seconds or your 45 seconds or whatever.
I want to encourage people to go as low as 20 seconds. That's going to allow you to go very,
very, very fast. That's going to actually challenge that phosphocreatine.
A piece a little bit. I want to encourage people to also go as high as 90 seconds.
So the honest way, the way that I will do it, not that it's about me, but just as an
example of something you could do, I do something in the 15 to 22nd burst range.
And I will generally hedge towards a two to one rest to work ratio.
So I'm probably going to rest 40 to work ratio. So I'm probably gonna rest 40 to 60 seconds.
That's to make sure that 20 second verse
is extremely high quality.
Cool.
I'm also gonna do something in the 30 to 50 second range.
Okay, I might go one to one work rest ratio.
The quality of those 30 seconds is gonna come down,
but the acid buffering is going to be extraordinarily challenged.
I also will do that with a triple or quadruple rest range.
So again, 30 seconds on, maybe two minutes off.
Now I won't be able to be working on my ability to handle the waste product build up there,
but I'll be working on my ability to produce more force over that time, which is another skill set.
And then all the way up to say what you do a minute, 70 seconds, and you can go one to
one there, or up to three to one.
You're going to be working on a little bit of his different thing, but that's exactly how
we hit both sides of this equation, working on dealing with waste, as well as actually
working on bringing in nutrients and getting that system a little bit more effective. So you could set that up across your week and just it could be something like day one is that
22nd burst window day two is that maybe 62nd window and then day three is maybe one all out effort
and we're done there. Let's talk about the specific protocols and adaptations related to maximum aerobic output
or maximum aerobic capacity is that sometimes called.
Sure.
Now we're moving past like that couple of minute range into like the five to 15 minute range
but at a maximum intensity.
So it's the highest you can go from there.
We're not talking about our last category of long duration here. Well, the beautiful part is we've already explained a lot of it because it's the highest you can go from there. We're not talking about our last category of long duration here.
Well, the beautiful part is we've already explained a lot of it,
because it's very similar to what we just talked about with anaerobic capacity.
It is primarily going to be a problem of dealing with waste products, especially at the end.
It's not enough total distance to be running out of muscle glycogen,
though it may start to creep down a little bit.
Fats, not going to be an issue, but certainly more oxygen transportation is going to be running out of muscle glycogen, though it may start to creep down a little bit. That's not going to be an issue,
but certainly more oxygen transportation
is going to be an issue.
So we're just hedging a little bit more
towards that side of the equation.
Towards the end of that workout,
no doubt about it clearing out waste products,
it's going to be a huge issue.
But really, oxygen and demand delivery
is starting to take more of a prominent role, because
we have had more time to clearly waste.
And if we're not good at that, we're going to be failing earlier than we need.
So the training for that needs to be a little bit at that exacting.
So a classic thing here is a one mile test, right?
This is going to last for most people somewhere between five and ten minutes. You're sort of right in this window. If you just want to practice
that once a week, we're done here, right? Exercise choice, same thing we talked about, right?
Pick an exercise you're comfortable with that you can actually do and you can progressively
increase in terms of the intensity. You're not going to have to stop and change your
exercise, you're not going to move around. It's like a circuit isn't great here because
you got to put one implement down, pick up another one. You want to be doing something
where there is literally not a second of off switch. So similar exercise choice principles
we just covered. If you become a real savage and you want to do repeats here, you can.
Endurance folks will do that a lot.
One mile repeats, 800 minutes, your repeats, things like that. I'm not sure if the swimming
distance equivalents would be, but swimmers would do this constantly. But you don't need to.
This is really hard. It's pretty hard in the system. It's very good for you. One to twice a
week of hitting this. I think you'll be in a really, really good spot. Frequency, we sort of discovered, we covered exercise choice.
Volume, we just sort of nailed.
And intensity is basically running you up to the top there.
Now because you can only do that so often, you want to add in another 40 or so percent
of your time being lower intensity support work for that.
So this is something probably less than 85% of your heart rate,
but higher than quote unquote zone two.
You gotta be working here.
This is not, I could have a conversation pace.
This is higher than that.
It's in between conversation pace
and the pace I need to be at
to run my fastest mile I've ever done.
That's that middle ground.
And you need to train that
so that you can continue to work on capitalization,
oxygen transportation, but
you're not burning down the house, getting all the up to 100, 100 plus percent of your
VO2 max.
Could I use a crude version of this where I say, okay, I'm going to exercise for 10 minutes,
I'm going to go as fast as I safely can and every week I'm going to measure how
far I travel. Yep. He's in that 10 minutes. Love it. Probably not on the same day that I'm
doing the anaerobic capacity work. Probably not. If you're probably okay to do after a strength training or hypertrophy workout,
as long as I didn't train legs.
You could,
it's probably gonna compromise recovery is the way,
so if you're gonna do a session like this,
I would probably do it on its own day,
unless you wanted to do something like speed or power,
then you could roll right into this and have no problem.
Maybe a strength day, hypertrophy day, I'm not sure you would do there because egg,
again, especially if you didn't have a sort of lower body exercise, you're going to be
compromised here.
But remember, these tend to be full body movements.
So even if you did arms that day, your arms are going to be compromised.
And you don't want to fail this because of local muscular failure.
All right.
So now I've got my work cut out for me.
I'm going to be doing five to six minutes per week of all-out work divided into 60, 20
to 60 second bouts with sufficient rest, and I'm going to give myself 10 minutes a week
of, in my case, it'll probably be running as fast as I can because I do enjoy running,
and I can do it safely, maybe uphill and see how far I go.
Yep.
If you want to combine the two, so if you're just saying, hey, I'm bought in, Andy, I want
to do both of these things.
They are similar, but they have independent benefits.
I'm convinced how would I build these into the same week?
Maybe do one of each.
That still gets you at quote unquote two days per week where
you're going to hit a high maximum heart rate. So we are to check that box up. So one
day can be a shorter length interval repeat one and the other one can simply be a five
to 15 minute maximum work and you're done. Long duration endurance exercise, the stereotypical endurance exercise.
Sure.
How far, how long, how fast, or how slow, rather, should I go?
And here I'm going to venture that exercise choice is one that we could click off, even
at this point in the discussion, because obviously it's got to be something that I can do for a long while without getting injured
Overuse injuries
There's a little bit of novelty we can actually throw in here. So
One of the things I love to do
For long duration endurance for people who don't love running cycling or swimming is you can do the really cool workout
Any number of things where you can put a little circuit
together, as long as there's not a lot of downtime
between one circuit to the next time,
you can actually do is something as simple as like,
maybe you're gonna do farmer's carries,
and you'll do that for, say, three minutes,
and you'll set those down,
and you'll go straight into a plank for a minute,
and you'll pick that up, and you go straight into
maybe body weight squats for two minutes, and you go straight into a plank for a minute. You'll pick that up and you go straight into maybe body weight squats for two minutes.
Then you go straight into another exercise
and you can sort of rotate things around.
Maybe you can do even some like shadow boxing stuff
or some jump rope.
You can do different gymnastics movements
and body weight movements.
And you can run that thing through
and you can basically get the exact same thing accomplished
and not feel like you're doing, oh my gosh, this mind numbing type of training, if it feels like
that to you.
Another way you can do that to actually even simplify it even more, we've done this at
Kenny Keynes gym plenty of times where you just maybe even pick three machines.
So you're going to go, I'm going to go 10 minutes on the roar and I'm going to go 10 minutes
on the treadmill and I'm going to go 10 minutes on the bike.
You can actually knock a 30 minute, quote unquote steady state session out in
and not feel those problems if those things happen.
So you can actually have a lot of fun there.
We will do a lot of times with our fighters.
We'll do things like put a very low load.
I'm talking sub 50% of your max on a barbell
and you're gonna squat and you're gonna do maybe a minute. You're gonna put that down and then you're gonna to squat and you're going to do, you know, maybe
a minute, you're going to put that down and then you're going to go over and do 50% of
a bench press.
You're going to put that down, you're going to go over and do 50% of a crab block and
then you're going to go over and do another one and you can actually run through this entire
thing.
You don't hit that many reps in any individual movement.
The load is very, very light and you can keep heart rate,, steady state, and do 15 or 20 or 30 different exercises.
And it's actually fairly fun and engaging to do.
And it's a little bit more specific than trying to give a 275 pound NFL player to run for
30 minutes, which is not going to be good.
So I'm just chuckling because I love to run outdoors.
And I've enjoyed runs on all my travels.
And I find it to be a great way to see different places.
I like moving through space.
But there are weather conditions and times when that's not an option.
So what you described as a terrific alternative.
I have to assume that the specific adaptation that's occurring here is related to the fat burning
system. And again, that doesn't necessarily mean fat loss overall, but fat burning system.
And yet I do have a question, which is, can you build enhanced microcapillary systems
into the muscles by doing this long duration cardio?
Yeah, absolutely.
Can in fact, depending on which paper you like more than the other papers, you may even find
evidence that this is a superior method than anything else.
So steady state endurance is very important.
I used to not like it as much.
There's just so much evidence now that suggests it's probably a really good thing for basically
everybody.
Maybe for some individuals, it's not in all year of their training, but if you're not
a high level athlete or have a very specific goal that's right in front of you, it's probably
best to do at least 20 minutes as a minimum, maybe 30 minutes of some steady state exercise
once a week for basically any training goal. Outside
of again, a couple of really specific scenarios that are happening. The other thing that kind
of kicks in here that we haven't really talked about is now we're actually reaching a position
where fatigue of the intercostals starts to play. So diaphragmic fatigue starts to run in an occasion.
So we forget, generally breathing is a contraction
to open up the lungs to change pressure
so the air will flow in.
And then the exhalation is passive, right?
It's just a muscle's been stretched,
it goes back to its resting.
When you get to a maximum heart rate inhalation
and exhalation become active.
So you're squeezing as hard as you can to open up
and you're squeezing to contract the blow air out. You're going to get fatigued that system, right?
Over time you have contracted, contracted, open up. If that system starts to get fatigued,
you start running into failure here. So you need to practice that. And this is when all kinds of
things like breathing drills to just simply training in this fashion. There's all kinds of
exercise devices for your lungs.
And when we say that, that's what we're really talking about.
The musculature around the lungs needs to not fatigue.
So that's the only other little component
I wanted to throw in here.
If we're not talking about acid buffering,
which in this particular case is not a problem anymore,
the time domain is long and slow, so we have plenty
of time to use fat as a fuel. We we have plenty of time to use Fat as a fuel.
We also have plenty of time to use anaerobic and aerobic
like calluses and clear out waste products.
So we don't really see pH being a problem
with this type of exercise.
You may start running low on liver glycogen
if you're going a very long time.
Muscle glycogen may start getting low,
but not really these for huge issues. You're gonna run run into maybe a little bit of a stroke volume issue,
but an intensity is not high enough to become a problem. You're more likely to break down
posturally or breathing mechanics than really anything else, unless again that duration really gets generally passed two hours
for most people. So those are the things that are going to limit us. So how do we improve it? What do we train? We went through the exercise choices. You also need to make sure you're training your intercostals. We
need to be training our diaphragm in some fashion. Again, it can be the exercise itself, can be your normal
training. The thing you need to be careful of here, and this is actually true for all the things we
just talked about. When we think about fatigue and we think about failure
and endurance, we really need to pay attention
to technical breakdown.
That is always the marker we look for.
So when we go through our stuff with our athletes
and they quote unquote fail, are they finished?
That's generally because we saw a massive technical breakdown.
You're done, like you're over there.
Not always the case during all your round of training, but this is something that really pay attention to. So if
you're on that bike and you're 40 seconds in and all of a sudden posture starts
to crunching over, I may stop the test. I may stop the training. It's like, no,
what we decided to failure was is when you lost your technique to some
sufficient level. So you want to pay attention to that too, because that's going
to determine your ability to perform well as well as maintain
efficiency, which is a really big problem here.
Tell me if the protocol I'm about to describe would be a reasonable one for
people to incorporate 60 to 120 minutes of long duration work per week.
120 minutes of long duration work per week.
So one way to accomplish that that I often use is to head out for a weight vested hike.
It's not a heavy weight vest.
It's maybe, I think it's eight or 10 pounds.
It's one of these thinner ones.
And if people don't have access to that,
you can bring a backpack with some items in it.
I mean, it can be as simple as that. You don't even need external load. It can bring a backpack with some items in it. I mean, it can be a similar stuff.
You don't even need external load.
It can just be your body.
That's why.
Okay. Great.
And do some hiking at a fast enough clip that breathing harder than I would be if I
just kind of shuffled along.
Yeah.
I might stop here there during some water, no big deal.
But I can carry on a conversation if I need to.
So it's a zone two-ish, but probably pushing a little bit harder than that for that duration.
Not a lot of deep soreness occurring after this, maybe a little bit of achiness and some
stabilization muscles that were used that may not be used too much, especially if I've
been sitting a lot during the week.
It kind of reminds me of how much I've been sitting.
But doing that all in one long afternoon, typically on a weekend, or doing two shorter
sessions throughout the week, maybe 45 minutes and 45 minutes,
and then working up the progression to longer, longer duration.
Seems like that would be something that most people should be able
to do, and that it would weave in well with any resistance
training or the anaerobic and aerobic
output capacity work that we talked about just a moment ago. Great. That's a fine version to do it.
If you want to go shorter and bring up the intensity a little bit, so you want to keep it more to
the 30 to 60 minute range and go, you know, closer into the, I can't have a conversation right now,
but again, I'm not at a blistering heart rate.
Then you could probably get that same thing done
in a smaller time window if that was a consideration.
So if you wanted to blend all three of these together,
you have a lot of wiggle room, right?
So you could do something like order.
If we're talking about this type of training,
you could do this first and then
finish with either one of the higher intensity stuff we talked about. So it could be
roped into the same thing. It could be its own independent day. It could be your sort
of active recovery day. It tends to be fairly restorative as you alluded to a little bit
there. So it's not that big of the deal to do this on your quote unquote, off day. If
you're those, if you're that type of person who like even on your off day, you have to do something physical, this is fine, right?
If you wanted to do it on a lifting day, especially if it's a power or a strength day, it's
probably fine. If you wanted to do it before the workout or after it, either way, you're
probably okay, probably best to do it after. If the primary goal is one of the strength
training adaptations, if it's not, if this is the primary goal,
do it first.
Amazing.
If you wanted to do it in the combination
with the other interval stuff, you could do it fine there,
you could do it before or you could do it afterwards.
I actually have no problem doing it afterwards
because that in effect, especially if you say nasal only,
during this training, will help the down regulation go.
And so you could finish that fairly well down regulator actually.
So it's kind of like a nice way to get thoroughly warmed up, go really, really hard,
and then give it a nice 20 to 30 minute slow back down.
And by the time you finish, maybe even on a three minute walk.
you finish maybe even on a three minute walk.
Nice low nasal breathing. Four second inhale.
Four second inhale, maybe five. You can play with the numbers a little bit.
Then maybe you don't even need to do the down regulation breathing after. You're just being a good spot. You wouldn't want to do this before. Do your intervals, finish your intervals, throw up,
lay on the ground,
sweat all over the gym floor, get up and go back to work. That's probably not our best strategy.
As people are hearing this all, they may be thinking, wow, this is a lot of work to do, but I've
been keeping track of the math here. I'm sure some of you out there are as well. And we're really
talking about 10 minutes of the of running or sprinting on the bike or row or once a
week, we're talking about six minutes or so of the much higher intensity, but short
bouts divided into rounds of 20 to 20 seconds to a minute with with rest in between.
And then some longer duration work out of 30 minutes minimum, but maybe as much as an
hour, even two hours, which in total doesn't really equate to that much time, especially if one can access these things right out their front door
or at home. And as we pointed out, you don't need any specialized equipment to do that.
Oh, and I forgot the muscular endurance. I wasn't trying to cheat there. Some muscular
endurance thrown in as well.
So that brings me to a question, which is,
if I'm doing my training for muscular endurance each week
for anaerobic capacity and for maximum aerobic output
and long duration, and given that all of that
can take roughly two hours for the typical person total
for the entire week, which I would
argue is going to give you back so much life literally in terms of longevity. You're literally
going to earn back years of your life productivity, your name, offsetting all sorts of metabolic issues
and enhancing your sleep and improving mood. I mean, there's so much data, so much data pointing
to all those positive benefits.
If I do all of these things, and I'm fairly consistent about them, am I going to be
metabolically flexible?
Am I going to have a well-developed fat-burning, carbohydrate-burning system?
And will I be essentially fit?
I mean, this is not leaving aside issues of strength
and hypertrophy, which were covered in the previous episode,
will I be fit?
I mean, to my mind, the ability to sprint very fast
if one needs to, the ability to go longer duration
if one needs to, and the ability to do something
in between, as well as hold a box overhead if necessary,
while installing a shelf or something like that.
These are the realities of life.
And to me, represent real functional world fitness.
If that's the case, is there anything
that we would want to add to this program?
Or would you consider that a fairly comprehensive
and complete endurance training system?
If we remember the target, which is,
I want to have energy, I want to look a certain way way and you want to be able to do that for the duration of your life for a very long life.
This style of training where you incorporate all of those areas of endurance gives you all weight management is not best done with any individual
style of protocol. So if you do a little bit of all three of these, you've checked that
fat loss box. You don't need to go on to anything separate for it. You've done all the things
then to cover aesthetics from that side of the equation, right? You've done the things to both enhance myocondria, to enhance
blood flow, increase oxygenation, and manage fatigue and waste development. Boom, energy's
there. Fatigue is there. I'm not going to get tired or have to quit or stop or sit down
doing any of these activities I want. At the same time, if you look at the literature on
mortality, one of the strongest
predictors of how long you're going to live is your VO2 max. So we've set up a scenario
in which you're going to hit all three of those primary goals by doing a combination of
this training. You're not going to miss any plausible adaptation from endurance training
and you should be set for regardless of your goal.
Incredible. And as I understand, totally compatible with strength and hypertrophy training,
provided that your goal is to also be strong and also selectively hypertrophy or generally
hypertrophy your muscles or maintain your muscles. For many people that are listening to this, I'm guessing that they have an interest in
building more endurance, but not just the ability to go further, but the ability to go a given
distance at a higher speed and to do it with better form and to breathe better and to
feel better before, during, and after.
For those folks, maybe you could spell out a program that combines these
different elements of endurance and does so in a way that informs how, for
instance, the higher intensity short duration sprints would be expected to improve
their longer duration work and how perhaps their longer duration work can
progress if they are careful to include some planks and some
wall sets and things of that sort. I asked this question specifically because I have to believe that
while there are probably some folks out there, they're looking to maximize their plank from week to
week to week. Typically, it seems that people fall into these categories of either wanting to get
stronger and get bigger muscles to varying degrees or to get better at endurance or to get better at everything overall.
Right now, I'd really like to just focus on what you think is a nice contour of a program
for the person that wants to get better at endurance, but do it with more speed, more stability,
and just feel like a strong endurance runner, cyclist, swimmer, or whatever happened
to be their endurance event.
Okay, great.
So let's just give an example.
Maybe you want to run your first half marathon.
Something like that, okay?
Maybe done a couple of times before,
but you just want to get better at that time.
I would probably put somewhere in the neighborhood
of 60 to 70% of your mileage in the moderate intensity zone.
Okay, so you need to accumulate mileage 60 to 70% of your mileage in the moderate intensity zone.
Okay, so you need to accumulate mileage and you need to be able to handle
what we call the tissue tolerance.
So in this case, your feet need to be able
to handle 13 miles of pounding.
It doesn't matter how much high heart rate training you do
or your fat, deliverability.
None of that matters if your feet are blown up by mile eight.
Okay, so in addition, we talked about how even training in that 70 to 85% heart rate zone
is quite effective at oxygen delivery, fat utilization, capitalization, etc.
So you're going to get a lot of direct endurance benefits from that work.
You're also going to be working on what's honestly going to be one of your limiting factors,
which is that tissue tolerance and that pounding. You're also going to be working on what's honestly going to be one of your limiting factors, which is that tissue tolerance and that pounding. In addition, you need to be efficient with your
technique and you need a lot of repetitions for motor skill development. So you want to spend
most of your time there. It's easy to recover from. It's not extremely demanding and challenging.
Awesome. That leaves you in another 30 or 40% of training. I would spend 10% of that in that like 22nd burst area. You're going to drive up fatigue
extremely high and you're going to really maximize your ability to recover from waste production.
All right, great. I would spend the remaining amount of time either on a little bit of actually
maximum speed stuff,
that could actually be in the 22nd burst.
If you're really trying to go as fast as you can, at the beginning of that exercise.
And then the rest of it, I would spend in that other zone, which is more of like the
five to 15 minutes, but you're probably going to want to repeat those.
And this is when things like 800 meter run, rest for double the time,
and then repeat that two or three times.
You actually need that in this scenario
because you're gonna need to be able to be running
for two, most people are gonna do a half marathon
and maybe around two hours or so, something like that.
And so you want a little bit of what we call repeated
endurance, right?
So be able to handle that higher, higher rate,
come back down, do it again.
At the same time, that's actually how you bump your mileage up. So instead of having this,
do more of these long duration distance runs, you can still get maybe five or six miles done
in a day. If you're going to do a one mile repeat or whatever number you're looking at. So
for a lot of people, that's kind of how I would structure it. That's honestly is very similar to what we laid out in the previous conversation
Which is getting this idea that more than 50% should be basically practice a
Little bit of work at the very top end of the spectrum but not too much and then a little bit of work at the other end
And you should be in a good spot a major mistake one would make here is only doing the long duration steady state stuff
And just sort of saying I'm gonna run a a five mile this week and then do six miles next
week and seven.
I said, that might work for you is I think we have enough evidence at this point both
in the scientific realm as well as most of the coaches.
I think in this space what agree with me is that's a suboptimal strategy.
So it could work, but we can do better.
In terms of the structure of a program like this, I realize that those structures very
tremendously different coaches and different books and different programs are going to say,
oh, you should run Monday through Friday with weekends off or every other day.
But in terms of this 70% 30% divide worth, 70% is going toward the specific event, you
know, doing the kind of work that you're going to do
during the specific event that you're most interested
in cultivating or improving.
And the remaining 30% coming from other sorts
of supporting work, how should one thing about
distributing that other 30% should it be
all geared towards maximizing recovery for the 70%
or in other words, could I do all that 30% work on one day?
I probably was split into two days. That's the reality of it. So if you're thinking, man,
Coach wants me to train six days a week, my schedule's tight. I can pull off four to five.
Okay. Great. What I might say is two of those days are just your your tempo, right? This is what like a runner would call
It's like tempo training kind of in that space. Remind us with tempo training is just like 60 to 80%
Effort range where you're like running at probably the same stride length and rate that you're gonna run your race at
Maybe a little bit lower, but something similar your practicing skill
You're accruing mileage and you're getting a, you're accruing mileage, and you're getting a little,
you're getting work and for sure work,
but it's not absolutely the fastest you can sprint,
and it's also not conversation.
So this would be the, what before we refer to as the 10 minutes
of fast running or 10 minutes of fast rolling.
This is lower intensity than that.
Got it.
This is work accumulation. Got it. This is practice stuff.
Then one of the days a week, I would probably enter in that 22nd, 32nd burst for a little bit of
speed there. And then one of the other days is when I would do that true high intensity, as hard as
I can for hitting a VO2 max, something like that. So that's probably how I'd break it up if I had like four days a week.
If you had five, you can maybe add in another day
where you do more of that volume accumulation practice work.
But that's a pretty good split.
Well, this is the point in the episode where I say,
thank you ever so much.
You provided an enormous amount
of incredibly interesting clear information. That's also actionable.
I do feel as if I far better understand endurance in its many forms. And even the cellular underpinnings of that and even
sub-seller underpinnings of what endurance adaptations are and how to foster those through specific protocols, things that not only I can do tomorrow, but that I will do tomorrow.
And where I hit my pain points, I'll understand
what's happening and the adaptation that I'm triggering.
When my legs are burning or I'm sucking for air
through my mouth, or I can calmly move along
just through nasal breathing,
I will now know what's happening in my body
and the specific adaptations that I'm triggering.
I think you also highlight something
that is vitally important, and I've never heard
it phrased as clearly as you did today, which is that it really doesn't matter how one
seeks out to achieve fat loss, provided certain criteria are met.
Even while certain forms of exercise tap into fat stores more than others, and you beautifully
illustrated the relationship between energy
utilization and breathing and the fact that we literally exhale fat to some extent.
Of course.
So, once again, thank you, thank you, and thank you. I know I'm not alone in recognizing
this information as incredibly interesting and actionable. And indeed, I do plan to
put it into action as I hope many of our listeners will as well.
Yet again, the pleasure is actually a whole mind
and I actually really appreciate the fact
that you let me go so far into metabolism.
My PhD is in human bioenergetics.
So anytime I can go many hours into metabolism,
I get very excited and I don't typically get that leash
in this
format.
So I appreciate that.
I know you understand your audience will love that.
Hopefully.
Oh, they'll love it.
And I think that they'll especially love it because they understand that if one can
wrap their head around even just a small fraction of the mechanisms that underlie a given
protocol, it gives both tremendous depth and meaning to that protocol
and makes it so much more flexible for people
that can really think about what's happening
as they're engaging in a given protocol
and know exactly what they can expect in terms of results.
Great, we've been on a bit of a journey here.
We've covered a lot of ground with speed development
and strength and hypertrophy
and now we walk through probably several hours here
of endurance.
What I would love to do next is to just give you
a more straightforward, not as much background,
not as much metabolism, none of the mechanisms,
right into protocols for someone who says,
look, I wanna hit those marks you keep talking about.
I wanna look good, I wanna feel good, marks you keep talking about. I want to look good. I want to feel good.
And I want to do that across my lifespan.
How would I build all these things into a protocol
that actually covers maybe the entire year?
And how would I be able to repeat that year after year?
So I almost have this evergreen sustainable year long
periodization structure that covers all the nodes I need to
if I want.
Everything we've talked about in these nine adaptations in this short series.
So I would love to do that in our next conversation.
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