The Peter Attia Drive - #250 ‒ Training principles for longevity | Andy Galpin, Ph.D. (PART II)
Episode Date: April 10, 2023View the Show Notes Page for This Episode Become a Member to Receive Exclusive Content Sign Up to Receive Peter’s Weekly Newsletter Andy Galpin is a Professor of Kinesiology at California State U...niversity at Fullerton, where he studies muscle adaptation and applies his research to work with professional athletes. In this episode, Andy returns to the podcast and continues the conversation about training for longevity. He examines the training practices of powerlifters, Olympic weightlifters, Strongmen/women, CrossFit athletes, and sprinters in order to extract insights that can be applied to the individual wanting to optimize for longevity. Andy goes into detail about exercise load and repetition, training volume, the importance of learning proper movement patterns, the advantage of working to technical failure instead of the number of reps, and much more. Andy ties the discussion together by providing a hypothetical training plan for an individual wanting to optimize for longevity and offers advice for avoiding injury. We discuss: Review of the function and organization of skeletal muscle [3:15]; Review of muscle fiber types [9:30]; Hypertrophy: changes in muscle fibers and the underlying mechanisms that make a muscle grow [19:30]; Defining sarcoplasmic hypertrophy and how it relates to the number of reps in a set [30:15]; Training for maximum strength: what we can learn from powerlifters and a hypothetical training plan [32:45]; Ideal reps, volume, and load for the powerlifter [44:45]; What should powerlifters do on their off days? [56:45]; Are there consequences of powerlifting on long-term health? [1:02:00]; Defining Olympic weightlifting: a test of power [1:04:30]; Training principles of Olympic weightlifting [1:07:45]; Tracking power output when training [1:17:15]; Frequency of training for Olympic weightlifting [1:22:15]; How post-activation potentiation (and the opposite) can improve power training and speed training [1:24:30]; The Strongman competition: more breadth of movement, strength, and stamina [1:32:00]; Training principles of Strongmen and advice for someone new to the Strongman competition [1:36:45]; CrossFit: a combination of weightlifting movements, endurance, and circuit training [1:50:15]; Learning from elite athletes, heart rate recovery, V02 max, and other metrics [1:58:45]; Optimizing towards being a well-rounded athlete as opposed to a specialist [2:09:45]; What we can learn from the sprinters about speed, acceleration, peak velocity, and technique [2:17:45]; A training plan for the “centenarian athlete” [2:24:30]; Debunking some training and exercise myths [2:33:00]; The “do nots” of training and tips for avoiding injury [2:34:15]; and More. Connect With Peter on Twitter, Instagram, Facebook and YouTube
Transcript
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Hey everyone, welcome to the Drive Podcast.
I'm your host, Peter Atia.
This podcast, my website, and my weekly newsletter, I'll focus on the goal of translating
the science of longevity into something accessible for everyone.
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what those benefits are, or if you want to learn more now, head over to peteratia MD dot com forward slash subscribe.
Now without further delay, here's today's episode.
My returning guest this week is Dr. Andy Galpin.
Andy was a previous guest back on episode 239, not that long ago in January of 2023, where
we discussed the structure of muscle fibers, the difference between the different types
of muscle fibers hypertrophy and how to start strength training.
I wanted to have Andy back because we never really got to finish what we started in our
first discussion.
And the reason for that, frankly, is because we went a little deeper than either of us
expected into the basic physiology of muscle.
And I want to be clear, I have no regrets about doing that.
I think that's an obligation that I feel is imperative through our podcast. Our podcast is known for going deeper into subject
matter than you'll typically find another podcast. And so we did that, but the price you have to pay
for that is sometimes you have to spend a little bit more time talking about things. So that's what
we needed to do in this discussion. So we start here by providing a very quick but important recap
of the first conversation around muscle cells functions, types of fibers, hypertrophy, things like that. But then we use that
to go into the rest of the discussion, which gets into the construction of a matrix. Now you may
remember if you heard the first discussion, we talk about the different phenotypes, the power
lifters, the weightlifters, the strongmen, the crossfit athletes, sprinters. And what we do here is we build out the principles of training
in terms of frequency, intensity, volume, rest, recovery,
everything that has to do with it.
We then organize all of that information
and ask the question, how would you tie that in
for someone who's training for the Centenary
and Decathlon?
Because if you'll recall, at least for me personally
and for my patients, we're really less interested in becoming powerlifters, weightlifters, strong men,
CrossFit athletes, etc. What we're really interested in doing is becoming centenary
in the Catholics. We're interested in being the most strong, physically fit,
able people who in the final decades of their life are functioning like people who are two
decades younger. As a reminder, Andy
earned his Masters in Health movement sciences from the University of Memphis, followed by a PhD
in Human Energetics from Ball State University. Andy's a professor of kinesiology at California
State University Fullerton, where his research spans adaptations from home muscle to cellular
level changes, which he has applied to his work with professional athletes for more than 15 years.
So, without further delay, please enjoy my follow-up conversation with Andy Galpin,
which will surely not be our last.
Andy, awesome to have you back for what is very unlikely to be part two of two.
This will just be part two of N,
where N is an integer greater than two,
and it'll be TBD on what that looks like.
In our first discussion,
which I think truthfully was pretty technical,
but I still think formed a very important basis
for what we're gonna talk about today.
So I predict that today's discussion
will be a little less technical,
but we'll assume that the viewer slash listener has some familiarity
with what we've talked about.
But for those maybe who a listen to it a couple of months ago and have forgotten or be are
not listening to it, I think it's probably worth investing a little bit of our time in
going over some of the major concepts.
So feel free to diverge from the line of questioning,
but everything I want to talk about right now
is just to give people enough background
so that we can get into the meat of the discussion
that you and I have already spent some time planning.
So let's start by explaining what the cells of muscles
look like and how they function.
When we say the term muscle, what we're typically referring
to is a collective group.
So when you think about like your quadricep or your thigh, it's actually four muscles there.
That's why we call it a quad.
We say bicep, either you do bicep, say it's actually multiple bicep muscles and orientation
insertion.
So in general, the way that humans move is muscles will contract and muscles actually,
at the end of them, will come together to form a tendon.
Those tendons actually connect to bone. So when you contract muscle, it pulls that connective tissue, the tendon, that pulls
the bone and you move. And so you've got muscles throughout your body up and down, they have
different orientations and they have different responsibilities. So some are meant to be what we
call anti-gravity. So this is to keep you up all day and they don't produce a lot of force or speed,
but they're meant to be non-fetigable. And others are the opposite. So explosion, power,
propulsion. If you just look at like the lower shank, so the calf muscles there. The gastrocnemius,
that big one in the middle, if you point your toe to your face that pops out at you, that's meant
to be for power and sprinting and jumping and the one that's actually lower, and your soleus is
meant to be on all day so that you can stand and walk all day and not
get the teeth.
Despite the fact that both of them come together to form the Achilles, that wraps around
the bottom of your heel, inserts the bottom of your foot and that's what makes your foot
go sort of up and down.
So in general muscle is meant to create movement.
Muscle actually does a lot of other things that are vital to health, including pumping fluid up and down. So blood will pool because of gravity
towards the lower part of your body. Muscle contraction is in large part what squeezes the blood
back up into your heart and into your lung. It is the amino acid reserve. So it's the place where
you store amino acids so that you can use them to create red blood cells or immune cells or anything else.
And that's also the primary place actually where you regulate blood glucose storage and
all carbohydrates.
So I could go on and on, but muscle in general has a very important function in your body
for movement there and as well as signaling.
So the last part to acknowledge here is we typically will call muscle and endocrine organ,
meaning it'll actually send signals out through the body through what are called mild
kinds or what some people will call extra kinds if they're coming out as a responsive exercise.
And that's sending signal to your liver, kidney, your brain, or belong or anywhere else.
So at the big whole muscle level, is what we call it, that's the general function.
Now within that, each individual muscle, so pick the sole guesser, whatever one you want,
is actually made up of billions, if not more, individual muscle fibers.
And those fibers or cells, that's the same actual term, myo fiber, cell fiber, all usos interchangeably.
Those are actually just basically long cylinders.
And so if you think about this like a ponytail,
so I don't have much hair left,
I'm gonna the same boat as you there, Peter,
but if I had some, you'd see a big long ponytail
and you would call that one ponytail.
Really a ponytail is nothing but a collective
whole bunch of individual hairs.
And actually you can think of skeletal muscle at least,
a cardiac and smooth muscleer, quite different.
But skeletal muscle looks very similar to a hair.
So it is a long,
long cylinder. It's very strong. In this case, it actually contracts where hair doesn't. But
that's the basic function of that. And so within that, you have a whole bunch of organelles
that do things. So if you look at the whole muscle, what actually happens is that's surrounded by
a bed of capillaries. If you talk about blood going into a muscle, and it comes in to be a big artery,
gonna go through a bunch of capillaries,
and those capillaries are really surrounding
and mixing in and out that whole pony tail.
So they're kind of all over,
and so they're circulating around the individual fibers.
And that's gonna get you nutrients in,
like glucose, or anything else,
and get you waste products out,
like carbon dioxide, etc.
Within that big long cylinder, the capillaries are around it.
You've got a whole bunch of things, and probably the most pertinent is you've got what are
called nuclei.
So these are myonucleae.
And so if you remember basic biology, the nucleus is what controls any cell.
So most cells in the world have one nucleus.
It's got a lot of muscle as unique because you've got infinite number of them basically.
Spread throughout the duration of the muscle. And that gives you a lot of what we call plasticity. And so the more nuclei you have, the more control centers to have, the easier it is to respond to
stressors, damage, adaptations, etc. And that's why skeletal muscle is so, again, adaptable to
various, whether this is good stimuli or bad stimuli, like in the case of space
flight or physical inactivity or whatever you want to be.
So in addition to that, you've got, of course, your mitochondria, which you've spoken
at length out of your career, and that's what's going to be able to use a lot of your,
or produce a lot of your cellular energy.
And then you finally, you've got what we call the contractile units.
And so the things that make your muscle fibers contract together and squeeze on top of each other
are actin and myosin.
And so these are two molecules that kind of reach up
the myosin grabs the actin and pulls it together,
smashes it literally on top of each other.
And that's why when you flex, say, a bicep muscle,
it actually gains height because you're stacking things
on top of each other and that requires the muscle
to go vertically.
So that's, I guess, the big picture of what muscles are, and then what they actually
looked like at the cellular level.
That was much more efficient than I would have done it.
Let's layer on another question.
You drew a contrast between the solius and the gastric nemius.
And although you didn't use the exact terms, you alluded to it that one is sort of slow
to fatigue, and one is fast to fatigue,
which of course is now part of another division we would layer on this.
So, can you explain at that cellular level what the difference is between the gastrocnemius
and the solius?
We call muscle fibers one-on-one, but really there's distinction between them, so maybe we'll
just take a quick, John back into history, and I won't make this too long, although I can love to. So
all the way back to the invention of the microscope, I'm talking about Leven Hook.
Many people discovered things, but you get, he gets a credit. Well, one of the
first things to actually use that microscope for was he started looking at
individual cell, he started looking at muscle actually in whales, in codfish,
and a bunch of other stuff, and he started to notice that some of these cells are really small and some are really big.
And that's the very first time we really started to functionally distinguish between, at that
time it was just sort of big fibers and small fibers.
And then pretty quickly after that he started to realize, well, some of them are really
red and some of them are more white.
And so for a big number of centuries really, we kind of distinguish muscle as these fiber
tight, they're these fibers, these cells, are they red cells or white cells.
And I took a long time to figure out why that mattered with that man.
And eventually, it became clear that the ones that are red are red because they have more
of those capillaries, they have more blood flow, they have more mitochondria, they have
more iron that all those things go into it, so they give an actual look of being red.
The other ones have less of it.
We didn't know for a long time after that, though, functionally, what that meant.
If you were to look back in some old textbook or had an old professor one from anatomy or
something on time ago, they might call fibers white, fibers and red fibers.
And so you'll hear them distinguished based on color.
That's the first distinction.
Well, as soon as histology came around and we started getting better microscopes and technology,
we started to realize, wait a minute,
we can actually test the individual muscle fibers
for their power output.
So this is their contraction.
So this is you take them out of the muscle,
you put them in a peach reddish,
you tie one end to a force transducer,
you try the other end to a fixed unit,
and you put it in a whole bunch of a bath of calcium
and ATP and a bunch of other stuff,
and those fibers just start contracting and limited, and you can actually measure how much force is being produced.
And so now we went from distinguishing these fibers via color, red versus white,
to now distinguishing them by their contractile properties.
This is what that term means. So are you contracting with a lot of force or a small amount of force?
And in fact, force wasn't really the distinguishing factor. It was speed.
And so because of that, we started the nomenclature
involved to now describe the mass fast twitch or slow twitch.
And I really specifically described the twitch
or the contraction speed.
So two ways the distinguish of fibers now, color or contractile
speed.
And then eventually, we started to figure out
there are enzymatic differences.
And so the ones that had more monocondria
were better at using aerobic metabolism.
So this is carbohydrate and fat metabolism.
Those are both, I'll robically need it.
And the ones that were white or fast were much better at using glycolysis from the anaerobic
part of the equation.
So this is in the cytoplasm outside of the mitochondria.
And so now we can distinguish these things via enzymatic properties. And so you can call them a fast twitch fiber.
You can call them a white or red fiber.
Or you can call them a row book or an aerobic
or oxidative or like lytic.
Again, depending on if you've ever had
maybe some of this stuff in high school or college class,
you might have heard them describe as fast oxidative
or fast glycolic.
And there's like, why is all this nomenclature exists, and that's exactly why it all happens.
And so, to come back to the beginning here, this is where it's going to really matter.
Initially, when this distinction was drawn, it looked like there was two types.
There's type 1 and type 2. That's just what they called them.
And type 1 is slow twitch, the red fibers, the oxidative fibers.
Type 2 with a fast twitch, all the opposite, right?
Well, in the 1950s-ish area, we started to figure out,
oh, wait a minute, there's actually a third distinct fiber type.
And that fiber type was more closely aligned
to the fast switch fibers than the slow-touch.
And so we started to delineate a little bit more.
So you have your type 1, and they'll stay way over here.
And then over here, you have a type 2A and a type 2B. Again, they are distinct and different,
enough from each other that they need to be called their own thing, but they're closer
together than they are close to the slow to the driver. So instead of why they called it
type 1 and type 2 and not type 3, it's because they wanted to make sure people recognized
they're really close to each other, but they're distinct. So we'll call them two A and two B. Well, some years passed and we actually
eventually realized that humans don't have two B. So again, depending on the express physiology
book you might currently be using, they might still be using the nomenclature of type two B.
Despite the fact that we've had genetic information since 1990,
that humans don't even have the gene to express 2B.
So like 2B is just a non-starter with human.
However, we do have what's called a 2X.
And this is actually, this is foundation stuff that you're going to need later in the conversation
when we talk about it the second half.
So humans to summarize have type 1, type 2A, and type 2X.
Well, felines and animals and bears, and stuff we've done biopsies and stuff
on bears, do have the 2b. Neuranes have 2b. And so most other animals have 4 distinct ones.
They have really, really fast one. These bees are ultra fast. 2x is pretty fast. 2a is slower
but fast. And then one is slower. So if you run the entire continuum, it pretty much lines up. So the ones that are pure type one have generally the more mildest congrier and they are
less fatigable.
They don't produce as much force.
Well, they do really do size, but they're slower.
And they do that.
As you move to 2A and to 2X, they become faster, but they become more fatigable because
they're more reliant upon glycoly carbohydrate and tablism. So that's
Generally what we're looking at with fiber types. So when you ask the distinction between how does the soleus and the gastroc compare the gastroc in most humans
Is something like 60 to 70 or maybe even up to 80%
2 a fibers and so they are very very fast. So the gastroch will, again, cause a fast contraction,
but they won't hold on for very long as it gets fatigued.
The solius can be up to 90% slow twitch.
And so this is a great comparison
because most muscles in your body
are some combination of fast and slow twitch,
but the solius and the gastroch
are probably the best example of the two extremes.
If you look in animals like mice, you can see a soleus that is 100% sole twitch.
For a number of reasons, humans never get that far down the line.
If I bibe-seed somebody in the soleus and they were 80% sole twitch,
I'd be like, well, that's pretty high.
And if they were 70% fast twitch in the gastrook, I would say that's pretty high.
That's what you can sort of expect in terms of muscle physiology differences between the
solace and the gastroc.
And again, why that function matters.
If you have the compromised solace, you're probably less likely to be standing, you're
going to sit, you're probably going to be less generally physically active.
If the solace is compromised, it's hard to move fast and powerfully.
How modifiable is that distribution? Is it purely genetic or is there a trainable component to the ratio of fast to slow
to which fiber in a given muscle?
It's extremely trainable.
It just comes down to exposure, which means stimuli and time.
And the more stimuli you give it, the more time you give it, the more it will change.
Now like anything else,
an asymptote exists here. So, if you are very untrained in your pretty inactive physically,
maybe even take new extreme, you go into a cast for two months or spaceflight, and you're literally
inactive, that movement happens faster. If you are pretty trained and well trained in months and
years go on, you start changing really, really slowly because you get closer to the end of the spectrum.
But there is really, I mean, functionally,
don't limit how far they'll go,
given enough total exposure.
To put you into like some realistic numbers,
the sole use is kind of hard, actually.
The gastroctis is a better one.
If you were to say completely untrained,
and you had an exercise for say five plus years,
and then you did eight weeks of exercise,
I don't even care what it is,
it really doesn't matter that much. I would bet 10 to 15% change in fiber type in that kind of a
time span. It wouldn't be that crazy. Sorry, just to make sure I understand what's actually
happening there, Andy. Is it turnover? Meaning, are you literally just expressing more type
two and expressing less type one so that if you compare the muscle biopsies across those eight weeks,
you've actually just displaced 2 into 1 due to making new cells and apoptosis of the old cells.
Really good question. Generally no. There's this idea called hyperplasia. So hyperplasia is when you
would grow a new cell. And that that is very very uncommon in normal human situations
It can happen with extreme eccentric training
Looks like it probably happens with a lot of exogenous testosterone use over many many years
But outside of like sort of extreme examples you can get it in cell culture and you can get it in
Animal models, but in human like normal situation type of pleasure is very
Uncommon so what more happens is the current fiber type itself
will transition its type, which is sort of tricky
because this, I'm not sure how far you want to go here,
but the reality of it is, remember how I said
there's three fiber types?
That's not actually true either.
There's a whole combination of what we call hybrids.
And so if you were to take any one individual muscle cell, it might be
entirely, say, 2A on one end of the cell, but it might be what we call a one, twoA. So this is a
single muscle fiber that expresses both type one and type two. Depending on the length of the cell,
there may be different spots. So they're not always the same type. So the same thing can happen
with 2A2X, by the way. In fact, you can have a triple high where you can have a 1, 2, a, 2x. So you can have all three being come express.
So they're kind of pluripotent and they basically have the potential to differentially
express themselves based on stimulus.
Or lack of.
Okay, let's talk a little bit about how everything you just said factors into some of the metrics
we're going to talk about.
These are the different types of performance and athletes.
Let's start with hypertrophy.
If you took a biopsy of my biceps,
and then you took a biopsy of a professional bodybuilder's biceps,
how do our muscle fibers look different? Are his significantly at the
level of the cell and the fiber significantly that much bigger? Does he have more of them,
but they're about the same size, but in aggregate, they're bigger in cross-section, of course,
is it a combination of both? Well, this is a lot of really interesting questions. Let's use the VL,
the mass of the lateralis, the outside quad muscle, as a better example,
just because we have thousands of biopsy studies from there.
So you ask a lot of really cool questions.
Okay, a couple of things to understand.
Number one, counting muscle fibers total
is a very challenging thing,
because the only true way to do it is
I need to take your entire muscle.
Thank you, everything up.
Yeah.
And half in counting.
Now, we can do some estimates.
You can take a whole muscle size, take the average size of the muscle fibers, higher muscle. Think everything up. Yeah. And half in counting. Now, we can do some estimates.
You can take a whole muscle size, take the average size of the muscle fibers, and then account
for our fluid and stuff, but that's sort of tricky at best.
So we have good data on these from animal models.
Cats, actually dogs and things like that.
Humans is challenging.
In general, fast twitch fibers, and let's just keep it fast and slow for now, not confused
people, are generally bigger than slow twitch fibers by diameter.
So they're generally wider.
But when you throw training into the equation, that all goes out the window.
I have analyzed, I can't tell you how many thousands of slow twitch fibers and they are bigger
than fast twitch fibers in that individual person.
Now, does that tell us anything about that individual? For example, if you look at an extreme athlete,
like an endurance athlete who is getting as much potential
out of their slow twitch muscle fibers as possible,
is that generally the scenario where you will see
remarkable hypertrophy of the type 1 fiber?
That's exactly what it is.
And so one of the things we see happen
is fiber type specific hypertrophy
with your classic endurance training
So throw kind of intervals and other things out the window for now just because scientists like it's hard to do
But if you do your steady state runner cycles swimmer rower things like that
I would generally be looking for their slow to fibers be very large if not the same size of their faster fibers oftentimes larger
When you're actually pulling out one muscle fiber at a time
their faster drivers oftentimes larger. When you're actually pulling out one muscle fiber at a time, you'll see some really wild stuff. So that can happen individually, but on an average,
that would be your answer. If you were to invoke any kind of strength training, you can distinguish
between power lifters or body builders or any of these things, it won't actually really matter
because at the level of the cell, while we're going to distinguish between all those,
probably here pretty soon, at the level of sell, it's not that different.
It's close enough to being the same thing.
If you compare it to how different it is,
then steady state cycling or something.
And so in both of those cases,
that would basically say,
hey, the 2A5 is gonna be very large,
but you wouldn't be able to pull a 2A5
or be like, oh, that's a body builder
and that's a power lifter.
And that's a weight lifter.
You would have absolutely no chance to do that.
The only thing that kind of throws a wrench here is specifically exogenous testosterone.
That will change the game in a number of important ways.
Specifically, satellite cells are going to be changed and total muscle fiber sizes is probably
going to get exceptionally large, which will throw it out there.
So again, just to make sure I understand, if you're going to compare my VLO to the VLO
of J Cutler, so world-class bodybuilder, if you're going to compare my VLO to the VLO of J Cutler,
so world-class bodybuilder, if you do an ultrasound, there's no question that the total size
of his muscle is so much bigger than mine.
If you can start yanking fibers out, it sounds like he probably has more fibers, probably
because he's using exogenous testosterone and I'm not, but it also sounds like his type two fibers are bigger than my type two fibers.
I would be very comfortable with that prediction.
They will be very, very large.
We buy up to one individual power lifter slash bodybuilder.
Some of those fibers were so large the closest comparator we have were rhinoceros, muscle fibers.
They were so not all of them, but I have them where they were so large.
Can you give me a sense of scale? How many microns are we talking about here as a fiber? I was like, they were so, not all of them, but I hand them where they were so large.
Can you give me a sense of scale?
How many microns are we talking about here as a fiber?
Or compare it to a hair if that's easier?
It would be, honestly, fairly similar to a hair.
So meaning you can see it with your naked eye.
It's so big.
Oh, 100%.
If I had it right now on camera, if you're watching this at home, and if I had my tweezers
out, I could pick one up on my peach edition hold it on camera, and you would be able
to see it in this camera.
No question.
They can be very, very large.
Even the smaller ones in human skeletal muscle,
like the VL, especially, you would see
all the smallest one, no doubt.
All right, so now let's talk about another component
of hypertrophy, which is, you know,
it's sort of funny taking a step back.
There is no other cell in the body
that we spend so much time thinking
about the actual size of the cellular unit.
We don't really care about the size of your hepatocytes.
We care about the functional units and how they integrate.
We care about the function of the hepatocytes individually and collectively, but we're
not really sitting there specifically thinking about it.
And therefore, I don't think I've ever given much thought to are my hepatocytes the
same size as your hepatocytes
and if mine get bigger or smaller, what's happening? And I'm guessing in the case of, you know,
naffledee, there's going to be some changes where there's both intra and extracellular fat accumulation.
But when we now think about a given individual who undergoes hypertrophy training and so
who undergoes hypertrophy training. And so objectively, their muscles have gotten bigger.
Let's keep this quote unquote simple
and not assume the use of exogenous testosterone.
So we're not really talking about hyperplasia
and the creation of denovo cells.
By definition, of course, now we know
that the myofyral has gotten larger.
It has expanded in diameter.
What has actually led to that?
How much of that is water, intercellular water?
How much of that is the synthesis of new organic matter,
vis-a-vis the amino acids, or something else?
So there's two main ways that a muscle would hypertrophy.
And we're going to distinguish chronic hypertrophy
or permanent hypertrophy from acute hypertrophy,
being, you know, you just left the gym right now
and your muscles are bigger full of fluid.
That's just what that would be cause.
So you've got sustained muscle growth over time.
This is either gonna be a result
of what we call contractile hypertrophy
or sarcoplasmic hypertrophy.
In either case, the muscle cell got larger.
The diameter is expanded.
It's gonna happen that way.
The question now is,
what actually changed inside that cell
that caused it to be allowed it to be permanently larger?
Well, in the case of cycloplasmic hypertrophy,
this is very new that we even thought existed.
Folks have been talking about this
from the bodybuilding perspective
in those communities for a very long time.
And we always call this sort of pro science
and then turns out some folks that micro-rovers
and his lab at Auburn, and stuff started looking into it, and found that actually was happening.
And so there's just another vindication for you pro scientists out there that sometimes
those guys are on the things.
Just because science isn't there yet, doesn't mean it's wrong.
It's a very good example, right?
It just hadn't really been studied.
So that actually happens.
A contractile hypertrophy happens as a result
of increasing proteins on those miocin and actin.
And so it may be important, maybe not,
but the mild filaments here,
you don't add more actin or miocin.
You just add more protein globulins to them
and actually just sort of increases their diameter.
And what happens then is you can imagine miocin
acting, working almost like you got a circle of friends
and you were to reach your arms, extend your arms out to the side, grab your friend's hand, and when you brought your hands closer to
your midline, your friends would then come closer to you. And if everybody get at the same time,
the entire diameter of that circle would get really small and expand. Okay, great. Well,
if I were to double my size, but my friends stayed the same distance away from me, and then my friend
doubled her size. What you can actually see happen is, of a sudden when I go to reach my hand out to
grab them, I'm already touching them.
Because we're so much larger if the whole circle didn't expand.
And so this is called lattice spacing.
So the spacing between these act and my essence is very, very important.
So if I just continue to get larger, what I would eventually do is tell my friend next
to me, hey, you scoot over a few inches because you're sort of crowding in my personal
space.
And then that friend would say, hey, friend over, same thing, same thing.
So what happens is just the standing circle starts to expand.
And so probably the biggest explanation for why muscle increases in its diameter is exactly that.
You've put more proteins in the contractile units in order to maintain optimal spacing so
they can reach out and grab each other and pull in for contraction.
The whole thing needed to space out a little bit.
It's like you invited a few too many friends to party.
Everyone's uncomfortable now.
We have to knock down a wall, make the whole thing bigger.
Have we bring in more friends?
We got to continue to knock the wall down and expand the size or else we just get too
uncomfortable next to each other.
When you experience contractile hypertrophy based on everything you've just described,
it sounds to me like that comes with contractile force as well because you're putting more hooks basically, you're basically
creating more anchors, i.e. actin-mias and filaments to grab and contract. Is that essentially
to a first-order approximation, a true statement?
Yeah, and this is actually true. He's explainable for a number of ways. Number one, in general,
especially early in someone's exercise and career, as you get
stronger, you will add more muscle mass.
And those are very highly linked.
That R score is not 100%, it's not 99.
It's not 100% the same thing.
And we'll differentiate that later.
Optimizing for muscle growth is not the same as optimizing for strength.
Optimizing for strength is not the same from optimizing for muscle growth.
So at some point, they start to diverge more and more and more,
but at the very beginning they're very tightly linked.
And so if somebody just wanted to be economical in their training,
you could probably get a little bit of both.
Well, you certainly would get a little bit of both.
If you wanted to optimize for one, then that is a little bit different.
And we'll distinguish all that later.
Now, as you continue on with your training career,
and you get stronger and stronger and stronger, then the link between muscle size and strength does start
to go away. But it never goes away entirely because of exactly what you mentioned.
If you're tacking on more contract-out units, it's not made me optimizing
strength, but it's going to come with some increases in force. And the easy way
to think about this is just look at whether it's powerlifting, strong man,
wrestling, MMA, you're generally
going to see people as you go up in physical size, you go up in strength.
That doesn't mean you couldn't find a 155 pound athlete who's stronger than 170 pound
athlete, you clearly could.
But if you look at old record scores, go higher and higher and higher.
So there is an intrinsic length there, but there a connection between mass and strength,
although it's not 100%.
So yeah, you're going to put those things on.
And I guess one important note here is, early in your training career, you really don't
even need to distinguish between the two, because both it's going to come along to the
right.
You add on some muscle, you're going to get stronger.
And if you just strength train, you're probably going to tackle some muscle as well.
They're both going to come along for the ride.
So you can be a little economical that way.
Andy, go back to the sarcoplasmic hypertrophy for a moment.
Just give me the background story on that.
I was totally unaware of that.
When I was in high school, of course,
all I did was read muscle and fitness and
bro science was my life.
I've been a little away from it.
Tell me what it was that the bodybuilding community
was proposing that science basically only really came to recognize.
In general, for a long time, myself and many other exercise scientists were sort of
proposing that if you wanted to get muscle hypertrophy, eight to 12 repetitions per set is the optimal range.
But yet, if you look at bodybuilders, they're doing all kinds of stuff.
Those who set to 20 or 30 or 40 different styles of training. And according to us, scientists,
that was not hypertrophy.
That was most care and endurance,
or that was strength,
and those would not result in hypertrophy.
And then eventually,
more and more research came out,
Brad Schoenfeld did much of this work.
He's incredibly prolific.
And Brad showed, well, actually,
hypertrophy is pretty much equal
from anywhere between five repetitions per set
to up to 30 repetitions percent if other things are quite
good for. Provided the RPE gets to the same point right the reps in reserve has to basically if to get pretty close to fail
you're not failure necessarily but exactly. At the end of 30 you need to be hurting as much as you would be at the end of
seven. Yeah, it's very hard because you're going to start hurting at like 15 much sooner. Yeah, exactly. You got to just bear with it.
It's much more time under tension and in some ways it's also more taxing to your cardiovascular system depending on the lift.
It certainly can be certainly can be. So what the bodybuilding community would say are things like, hey, if you lift in this fashion
five to ten reps, you might increase contract diet units and that's why you're getting stronger. However, if you were to go higher repetition ranges, it's going to be coming from circle
plasma hypertrophy. And why that matters is that's almost exclusively explained by increases
in fluid retention. And so it is non-contractile hypertrophy. So this is why you can get bigger
but you're not getting stronger. That's the function of extinction. And again, that's
like something that we were just like,
no, no, no, no, it doesn't happen.
There had been like a couple of papers,
but the technology wasn't there, honestly, to measure it.
Tell us some assays came around
and Mike really got that stuff going
and it was like, oh crap.
And now it looks like the story's actually pretty clear.
Mike has a wonderful review paper on this stuff
and you can actually see a graph he's developed.
And you can look at when cycroplasmic hypertrophy happens, when contractile happens and what happens over the course
of your training experience.
And I think it actually explains what's happening pretty nicely.
I think that was the perfect intro to what I think would be a really elegant framework
for now how to talk about a series of rows and a series of columns
that make up a matrix.
In our first podcast, we spoke about the different types of athletes.
And then we talked about the different variables that go into training stress.
What we didn't do because there simply wasn't enough time was filling that matrix.
And that's what I'd love to do today.
So I went back to is what are
the different phenotypes of interest. So we're going to go with a power lifter, an Olympic weight
lifter, a strong man, a bodybuilder, a crossfit athlete, a track and field athlete, and then we're
going to look at them according to, you know, the following. If you're training to be specifically that athlete, what's your frequency of training?
What's your intensity, for example, as a percent of 1 RM or VO2 max?
What's the volume you're doing?
How are you thinking about sets and reps?
What's the rest?
Recovery?
And is there any other sort of skill-based training adaptation that's necessary?
I acknowledge this might take us a while, but I think this is a very
elegant way to synthesize so many of the concepts that were in the first episode of our sit-down.
And I think in many ways this is kind of the rubber hitting the road. Now, I'll tell you that my
ultimate goal in doing this, Andy, is to now extract from each of those phenotypes the learnings
for what I consider personally
the most important phenotype, which is not powerlifter, Olympic weightlifter, strongman,
bodybuilder, etc.
But rather what I call the centenarian de-cathlete.
In other words, even though I'm only 50, so much of how I think about training is for
the 90-year-old version of me.
What do I want to be able to do at 90?
I have a pretty good sense of what it is.
It's quite audacious.
What do I need to do for the next 40 years
to make sure that at 90,
I'm functioning to be honest with you,
like a very fit 70 year old.
That's the aspiration.
So we'll end with that if we have time.
If not, that'll easily be part three.
But let's start with the order that you presented them in,
which was starting with the power lifter. So again, just for folks listening, powerlifting is a very,
very specific sport. It consists of three and only three lifts, and you are scored on the basis
of the total amount of weight you move in a deadlift, a bench press, and a squat. And that's it.
Nobody cares what you look like. Nobody cares how fast you can do that. Nobody
even cares how many reps you can do, right? There's nothing that goes into it except it's
a number, a plus b plus c equals total and that's it. Now those guys are strong as hell for
what they do. Maybe give people a sense of numbers, pick two different weight classes
and explain to people just how strong a power
lifter is in those three lifts.
To really clarify, when we say strength, you could also think about force, I'll say those
interchangeably.
And, well, in the real world, if somebody were to be able to drag a train or something, I'd
be like, well, that's a strong person.
But technically, maximal strength is what's the maximum amount
you can do one time.
And I know you said that a second ago,
but I really want to make sure that the audience heard
that correctly.
Yeah, because the name power lifters
a bit misleading here, which I think you're about to explain why.
That's exactly right.
Power, the difference between force and power, is speed.
And so another way to say this is, if you take speed,
multiply that by force or strength. That's how you get power. And so implicit way to say this is if you take speed, multiply that by force or strength.
That's how you get power.
And so implicit in that is power is comprised of both strength and speed.
So there's a speed component to it.
In the case of the exercises you listed in power lifting, there's no speed component to
it really.
They're trying to move fast.
They can't, but they're not scored on speed.
There's no clock.
It doesn't matter.
And I'll have a fast thing move.
It is explicitly a test of pure and absolute strength.
What is the most amount you can lift one time?
There are three different exercises we tried in,
but you don't get to do it for three or four reps
or it's not a, you know, who can we do the fastest?
It is who's the maximum thing you can lift.
So to give you some examples,
I have worked with Steffi Cohen a little bit,
not much, but just a little bit of my career.
And she has 25 or 27 wood records. I have worked with Steffi Cohen a little bit, not much, but just a little bit of my career.
And she has 25 or 27 wood records.
One of her competitions, I think, she weighed 119 pounds.
And I think she deadlifted 525 in that competition.
She's deadlifted 585, I believe.
So getting in the stratosphere of 5 will over 5X body weight here, which is absurd. She probably dead up to
his herd thing, but she's still probably benching 200 something and squatting well over
the 400s. So as 120 pound female, that's pretty strong.
It's simply unbelievable. It's totally unbelievable.
I was dead lifting today, right? Today just happens to be dead lift A for me. And because
I no longer can like I peeked at 18, it's a little depressing, right? I just so far. That was
my peak in deadlift. Well, I mean, I don't know that I even cared a lift as much as I did.
But now I do different things. So today, the main set was four rounds of one minute as
many reps as possible with 350. It's a different stress, make no mistake about it.
It hurts in a totally different way.
Yeah, do 315 as many times as you can in 60 seconds,
rest three minutes, and keep doing that over and over again.
I hope Beth got a razor got fired for that,
one of the two.
Whoever programmed that for you.
There's no way I'm doing, no, actually I told Beth
after and she was like, what was your intention with this?
And I was like, actually, yeah, anyway.
But like, even at my strongest, I couldn't do five, 25.
But my strongest, I weighed 160 pounds.
So that's a staggering amount of movement.
And you've got good levers for pulling.
You've got long arms.
You're probably like pretty efficient
at that lifting out as soon.
That lifting was my best of the three, how far?
Yeah, bench is probably your worst out of soon, based on it.
It is.
I will embarrass myself by saying how much I could bench.
I guess I should finish this story.
Two 70 was my best bench at a weight of 160, which is not that good.
I mean, let's be honest, it's not that good.
It's not that terrible, though, either.
It's okay.
So if you want to look at like the crazy top end of the scale, I'm unfamiliar.
Yeah, let's tell people more about like what?
And I guess in parallel thing, it is a little complicated because you do have to consider
tested versus untested athletes. It's a pretty big difference.
Yeah, let's just give you the maximum human potential on all the steroids. Who cares?
All the gear, all the squats, suits, whatever.
My friend, AJ Roberts, I think his best squat was 1250 or 1240.
That's just hard to believe that's possible.
I think he was 308 pounds for that meat.
So this is, you know, 4x squat.
I don't know what the like all time, all time,
all time record is right now because it's so hard.
But I think it is north of 1300 at this point.
It's not common, but people have pulled a deadlifted 1000
and people have benched a thousand.
There's a lot more people who have squatted like 1100 plus.
There's a decent number of those people.
But there are a handful of people who have deadlifted a thousand
and a handful that have benched a thousand
with all the gear and all this stuff.
But who cares? It's like half a ton.
They're taking off the bar, holding it, touching it.
It's absurd.
It's simply absurd.
Okay. So we've established that despite the hiccup in the nomenclature, these people are insanely
strong.
Again, I would encourage everyone who's listening or watching, you may never desire to do a maximum
rep, deadlift, bench press or squat.
I personally have no desire to ever do it again.
Ever.
There's never a day I'm gonna put enough weight on a bar
in any of those three lifts to even come close to that.
That said, the principles of how they train matter a lot to me.
So let's start with, well, you can take them
in any order you want, Andy,
but let's just talk about frequency.
What are the sort of guiding principles
for how you take an athlete who comes to you?
And I guess maybe for the purpose of this discussion, Andy, let's assume that all of the
guidance we're going to provide is not for a world class athlete with an enormous training
age.
Conversely, let's also assume it is not for someone who has never lifted a finger.
Again, I think just for the
sake of simplicity, why don't we assume that in every situation, you're taking a person who has
some exercise exposure, but not specific to this endeavor. So in this case, you're talking about
a person who grew up playing sports, maybe they're reasonably fit. They still muck around, you know,
they play some pickup basketball, maybe they do a little bit of this and that. They're no stranger to the gym. They understand
what lifts and things are. But truthfully, they've never been to a powerlifting meet. And they're
coming to you saying, Hey, I would really, I'd like to compete in the 50 and up, you know,
or 50 to 55 powerlifting thing. So guys shows up with that. Tell me how you're walking about his
training program. I want to make two slight distinctions inside of that. Distinction one is what is
theoretically technically optimal. Distinction two is what's probably more realistic and practical.
Okay, let's always feel free to give both of those. I distinguish these in my world as efficacy
versus effectiveness. So max efficacy is exactly the former there, theoretically, if you can do
everything to perfection, you will have the best results. Effectiveness is in the former there, theoretically. If you can do everything to perfection,
you will have the best results, effectiveness is,
in the real world, when you stay up late at night
because your kids are sick,
and you got a little extra deadline at work,
and that's gonna cut into your training,
what's the best you can do?
You just described last night, for me, I hope.
I hope.
So, one thing that's gonna, the whole truth,
throughout all of this matrix, we're gonna cover,
is specificity is always your answer.
If you want to get better at writing, you need to write.
If you want to get better at sprinting, you need to sprint.
If you want to get stronger and you want to get better at picking up a weight, one time,
the heaviest you can pick it up.
That is by far the most direct route to go.
Meaning in this case, you should practice every single day,
picking up 100% of your max.
Wow.
Theoretically, that's what specificity would tell you.
Distinction two, that's not realistic.
The injury for this person you described,
injury frequency is too high.
Now, if you are a truly elite athlete,
you might do something close to that.
If you look at the Bulgarian method, this
would be weight lifters, not power lifters, but similar. They're going to do a one-watt
max in the snatch, clanderc, and squat every day. This is what they do. Now again, these
are people probably on assistance. They are five, six, seven, eight, nine years into their
training career. And in between, they're getting massages. And so like, in theory, if you really
wanted to max my specificity,
you could do that, and many have done that.
Anemia, so the monoglyl, one of the pocket hercules,
if you want to go to the black guy.
Now you didn't do it for all of this training,
for all of your round, but certain phases of this training,
that's what you would do.
High specificity, you're going to get better
at those things, no question.
So to peel that back, anything besides that is less specific.
But you have to then start hedging towards,
okay, am I gonna get hurt?
That's not realistic for the avatar you described
and all the practical implications.
So what you wanna do though is get as close to that as you can
while not inducing overload injury, all those stuff.
So realistic scenario, probably something like
one to five days per week, you work that movement pattern.
So, realistically, two would be good for a lot of people.
So, if you want to get stronger at squatting, squat twice a week.
If you recover well, and you squat well, and your mechanics are well, three days a week,
that would be a really, really, really good program.
But you could get very strong, very strong, doing two days a week, in that movement.
So, if you wanted to do all three, like in powerlifting, maybe bench twice a week, maybe deadlift
once a week, maybe squat once a week, and like that, maybe if you wanted to squat twice
a week and deadlift twice a week, you could maybe get away with that depending on other
variables.
So it could be as little as two days a week of training because you could do a bench squat
day and a bench deadlift day potentially.
It could.
And for a lot of people, the person you're describing, they would get stronger.
Wouldn't be optimal, but it would be certainly effective for a lot of folks.
If they said Andy, I'm willing to be in the weight room four days a week.
I'm really optimizing on this.
If I'm going to be in the weight room four days a week, are you basically going to figure
out a split where you get three of each in those eight sessions or something to that
effect?
I'll tell people to look into what's called conjugate. There's many forms of this,
but this would be the West Side Barbell Louis Simmons form of conjugate.
And that's almost exactly what they describe, right? So it's a little bit of pure strength work
at the beginning. There's a muscular endurance phase, basically. There's a speed phase to it,
and then there's a strength phase to it. And they just build that in, and they actually just
sort of rotate it through Ben Squad, deadlift, Bench squat, and they just power through that way. So that's
a very easy model. And so you're saying that they would do that in any given workout or
across the week, it's spread out that way. Sorry. Yeah, across the week. So basically
you'd walk into gym, you're going to do a max deadlift, and then you're going to do
some assistance work in your low back, your glutes, your hamstrings, or whatever is needed.
The next day you come in is maybe a max bench, and then tricep workshops, older work, rear delts, knack, or whatever, etc. And then they come in,
you kind of follow it that way. The next question is, is the only time you're going to have this
athlete moving insanely heavy weights in the three formal lifts? Or do you have them do very heavy
things that are accessory? So I'll give you an example. Do you have them do very heavy things that are accessory? So I'll give you an example.
Do you have them do very heavy hip thrusters
or very heavy incline bench press
or very heavy military press
or very heavy front squats, i.e.,
things that they are not going to compete in,
but have a high degree of overlap
with what they're competing in.
Specificity wins here.
So you're gonna say no
because you're not a professional athlete
who has all the time in the world,
just do the lift.
I would say stick mostly to the lift. Now even for this person is not because they're not a professional athlete, you can make the argument.
They need variation more actually because who really cares if they optimize your strength gain.
I'd rather push a little bit more towards overall safety and variation will give you that because it's less overuse of the same movement pattern, the same loading pattern, the more variation
you get the less specificity, so the less direct adaptation, but the less likelihood of
overuse.
So in this particular person, I would probably, but if we really said this, I would say
it here, maybe I'll say it this way.
The core of our day when we come in is going to be that exact movement.
It's going to be a marble back squat in your stands the way that you're going to compete.
Great.
Certainly within maybe the eight weeks prior to this competition.
Outside of that, though, when we call off season,
we would introduce variation, do other stuff.
While they're in that specificity phase,
though, we might do our primary lift,
so we kind of call it.
And then after that, we would do a ton of accessories.
So we might do our hard work on our marble back squat,
and then maybe we go to a goblet
squat.
Maybe we do split squat.
Maybe we do lateral launches.
And we would do other stuff for verse hypers and things like that.
So you would want to use all those, but those would be what we call accessories or supporting
stuff.
And you would probably go to higher repetition ranges for those.
You wouldn't do a max effort step up.
You might do set to five, eight, something like that to really support the
joints and make everything feel good, but you keep your pure, pure strength work to that core
lift. And when you're in that, let's just pick one. Let's just pick the deadlift, for example,
what's their rep range? You're going to have them working in. Is there a number of reps that
is so high that it's getting you too far away from max strength? Five is sort of the number.
Five and less. You get starting past past 5 you start losing worst production.
I used to know these tables off by heart from when I was younger.
I believe 5 reps is that 85% of typically 1 RM that you do 5 for.
It totally depends.
Actually it depends a lot on fiber type.
It's sort of funny off, but it depends on the movement.
The same is not true for deadlift versus the bench. Those numbers go way off.
So it's a rough ish number.
There's actually a chart called Prelepin chart.
We'll put it in the show notes.
What the chart does is it tells you, there's been a handful of studies on it at a New
Zealand, some power lifters and stuff, but this is from the Russian literature, I believe
originally.
But anyways, it tells you how many reps to do throughout the week total at a given percentage.
So in other words, hey, between 70 to 80% accumulate this many reps, between 80 and 90% accumulate
this many reps, accumulate 90, 95, etc.
And it gives you a range of reps to stay within in terms of total per week.
And that's pretty good because it'll tell you sort of like, here's the amount of max effort
you can get away with.
And then here's how much supporting work you need to do
to make sure that stuff can happen.
It's generally pretty effective to get you close.
Now, to do this, you need to know your one RM.
Mm-hmm.
Okay, so this is a bit of a side,
but it might be relevant.
There are these devices, I forget the name of it,
I actually have one, and I enjoy using it.
I can't remember the name of it though.
It's a little thing that sits on the ground
and it has a strap that goes on the bar. Oh, velocity transducers, yeah. Yeah, yeah, yeah, and I can't remember the name of the though. It's a little thing that sits on the ground and it has a strap that goes on the bar. Oh, velocity transducer, yeah.
Yeah, yeah, yeah. And I can't remember the name of the one I have, but I quite fancy the
thing. Probably Kimmelware.
No, I have a different one. It starts with a V, I think. But anyway, if I do a set, let's
say I'm doing a set of fives, if I want to do five sets of five one day, it's measuring
the speed in feet per second or meter per second of each rep. It knows the weight, so I tell it how much weight I'm putting on and it's
measuring the velocity.
And it's telling me based on each rep two things that matter to me.
Right. One is what's my projected one RM based on the speed that I'm moving
that and what's my level of fatigue.
As I've learned, the lower the weight, the less accurate it is.
If you have 135 pounds on the bar and you're warming up, there's no amount of
speed you can put on that that will get you anywhere within what its prediction is. But once you get into
that five rep range, it's pretty accurate. Do you think that's accurate enough for someone like
me who doesn't actually want to do a one RM? Or do you think I'm just being a wussy? You are being
wussy. Yeah. But the other thing you can do is just do a rep max test.
So there's any number of online calculators put away on their comfort with and do it anywhere
between three to 10 reps.
And then you can say, okay, I did 200 pounds for eight reps.
And it'll say that's your one RM and then go off that.
Yep.
Now, one one caveat I'll give you there.
Those estimates will go up to like 20 reps per set, but the accuracy is awful.
So if you're going gonna do a max test,
I generally recommend staying below eight reps.
If you've been sick between like three to eight range,
that's gonna give you a pretty accurate score
for most people.
You said something earlier that I now,
I think kind of resonates.
I have never found those calculators to work for me.
Oh, you're a slow twitch guy, yeah, there's no way.
There's no way.
I think I'm a slow twitch guy, and therefore,
I can do way more reps than you would expect.
And therefore it tells me I should be able to lift more at one R M and I can't.
Yeah, there's no chance.
Whatever you're doing for at your 85% you're doing 15 reps.
I'm going to do four.
I'm a super fast twitch guy.
That's the other thing I think that is you need to couch that with your own
genetics and training history as well.
Okay.
How many sets are we talking about here?
So if I'm coming into the gym saying, okay, well, today's the deadlift day.
And let's just say I'm doing the kind of the Westside Barbell approach where the main set
of the day, the working sets are around my deadlift.
And then I'll do the accessory and endurance stuff later.
We've established you don't want me going above five reps.
Once I've done my warm up, how many working sets would you have for me in that day?
Yeah, so maybe I could answer at the very beginning.
You can answer this whole matrix for strength with just this thing called 3-5.
So the 3-5 concept, 3-5 days per week, 3-5 exercises, 3-5 reps per set, 3-5 total sets,
and then 3-5 minutes rest between each set.
It's pretty universal. That can
take you as low as three days a week. You're going to do three exercises for three sets of three.
Now the intensity has got to be high. It got to be a lot of load, right? It could take you all the way
to five days a week, five exercises, five sets of five. And that volume is going to be really
taxing. Again, if you're loading it appropriately, since we're under the powerlifting category.
But just to be clear, Andy, that's the strength matrix.
That's the strength column here is regardless of which of those athletes you are,
when you want to focus on your strength part of what you do,
which every one of those athletes has to be strong, including the sprinter.
You've got to be in the three to five.
Yeah, and now you could also say, again, I already said earlier, one to five, so it's great.
But this just makes kind of the real super easy for people to understand. I certainly didn't invent
this. This has been around for a very, very, very, very long time. You'll find this in books in the 1990s
and well, earlier than that. But it's an easy one kind of one-liner for people to remember for strength.
So it's days, exercises, reps, rest, sets, all that, right?
So again, since we're in powerlifting and since we're in strength, that three to five only
works though, if you're loading that heavy, if you're going light, that's not going to
work.
And just to be clear, let's explain to people what that means.
Do you prefer RPE or reps in reserve?
Either way, you want to just explain to people what those two mean and you prefer RPE or reps in reserve? Either way.
You want to just explain to people what those two mean
and how they can use it to think about this.
RPE, rating of perceived exertion, how hard is it?
You could do this scale of six to 20,
it's original board scale, you could do it one to 10,
you could do it one to five.
Whatever the top of it in the scale
is the hardest repetition you could ever do,
and you scale back.
So you don't typically need to always be
at the height of the scale there, but you can't be, if you're back. So you don't that typically need to always be at the height of the scale there,
but you can't be, if you're going on a scale one to five,
you can't be at two on this thing.
Four is probably the sweet spot.
Rips and Reserved is another similar idea
where it says like, if you thought you could do 10 reps
on this, and I want you to do two reps and reserve,
that means I want you to stop at eight reps, right? So you left two repetitions and reserve, you left do two reps in reserve. That means I want you to stop at eight reps. So you left two repetitions in reserve.
You left them on the table there.
Same thing would be strength.
So like, hey, we're going to do a set of four here.
I want you at a one rep in reserve.
So you're going to get that into four
and go, I would have one left, but I wouldn't have two.
That's certainly wouldn't have three.
I would have one left, but I'm going to stop right there.
So similar idea, just a different way to express it.
Yeah, Reppin Reserve for me has always made a little more sense.
I think it's easier to explain to people,
but at the same time, you have to know what failure is.
It's not something you can figure out by yourself.
You have to have the experience of dropping a bar on your chest
and having the guys run across the gym to pick it up.
Like, you've got to know what the-
Well, they're easier ways to learn, but that's one of them, yeah.
Yeah, yeah, yeah.
But you know what I mean?
Like, you sort of have to have been through the ringer of,
I think I have one more, and you do versus,
I think I have one more, and you don't.
And obviously it's much safer to figure that out
on a deadlift than on a squat, for example.
I mean, honestly, like, just go on a machine.
Who cares?
Like, just get a rough idea, right?
You want to get super safe. If you're not familiar with all this stuff, go on a leg press machine, go on a machine. Who cares? Like, just get a rough idea, right? You want to get super safe if you're not
familiar with all this stuff.
Go on a leg press machine.
Go on a leg extension machine.
As much as like, you don't love that.
Just get close because you're right.
RPE and RER both fail epically when people
are not highly trained.
They think, oh, that's probably close.
And really, you thought that was a two, RER,
but that was like a seven, RER.
Like, you're not even close to where you're at.
Most people are just stronger than they really are.
Way stronger.
They have much more in reserve.
Okay, so we're assuming that for everything we're talking about with respect to strength,
the individual will get to the point where they truly understand how many reps they have in reserve.
And now for the three to five system to work,
are you talking one to two reps in reserve or needed?
That's probably pretty close, probably closer to one, the less comfortable you are fine,
but remember, you're not going to get stronger by going at so maximum weights.
You're not going to optimize it.
So like the whole idea of getting stronger, you got to test the limits of sort of where
you're at within a safe range.
Of course, and if you're just starting, take your time, ramp up, take six weeks, take
eight weeks.
You have a lot of time.
You've got 50 more years, Peter, like we're not in a rush here.
But yeah, eventually we got to...
I only have 40 years, but...
You get it though.
So do all the caveats inside be smart with this stuff?
We already put one other caveat that I always make sure to say here earlier in the conversation,
which is, hey, if you wanted to get stronger and you're really untrained, you don't have
to go this heavy.
You can get very strong doing set to 20.
You'll get there.
But this avatar was someone who said it's past that point a little bit.
So they needed to really get closer to optimal strength.
So this is why we're going a little bit heavier in regard there.
Before we leave the power lifter, I want to bring a few other things into this. So again,
we're not in this discussion, specifically optimizing on total health. Correct.
Correct. We're really optimizing around this person being a power lifter. So so now I come
back, you know, say, Andy, okay, I got it, man, I'm all in on this. You know, I'm going to basically
do three to five exercises, sets reps, et cetera. But I said, hey, look, on the other three days a week, is it cool if I do a bunch of cardio?
And again, I'm not talking about this through the lens of health.
I'm saying, will it make me a better power lifter?
Make you a better power lifter?
No.
So what would you advise that I do on my off days if the objective is maximizing my strength?
When I was kicking around these scenes a lot, power lifters were notorious for being
the laziest sons of you ever seen in your life. If they're not lifting, one of them
acts, they're going to be circling Walmart for two and a half hours to get a closer parking
spot. No. That is not a joke. I've been in that Jeep. I've been in that Jeep and just driving
around. You're just like, oh my God, it's just like saving every calorie. Okay, great.
I think more recently, people in that community started
to realize, I need some level of fitness,
because I can't handle the training volume.
If you're pouring sweat, getting through your warm up
and tying your shoes, you probably shouldn't be doing
one right maxes all day.
Like, do we need to get fit first?
They have to have some level of fitness.
So what I would say is this, do the stuff we talked about,
maybe finish each one of those workouts
with a set of eight to 10 or 12. Just to pump a little bit of volume in there that'll get you
in a little tiny bit of fitness will be achieved kind of from that stuff. On your off days, if you truly
want to maximize strength and you're fitting off, then just rest. Do other stuff, maintenance,
fitting off, then just rest. Do other stuff maintenance,
no mobility, breath work, all the other recovery stuff, just hedge heavy, you can. If you're just antsy, got a move, got a
move, got a move, fine. But this is be like a zone two or
lower movement, right? Just don't do much work. Because every
amount of work you're doing is just contributing to systemic
fatigue. And remember, it's not just about doing things like preserving muscle glycogen, what you
have to do, but it's not a huge deal if we're doing, say, three sets of three.
It's not going to drain you of that much muscle glycogen, but your nervous system requires
carbohydrates from metabolism.
Everything else is got to be optimized here.
And that stuff takes a long time to recover.
We've got to restore muscle glycogen, a phosphocreatin, and ATP, all that helps them. So there's just no reason
it would give you an advantage to do more endurance work in between as long as you have some baseline
fitness. And that's the one time where people do see gains from it is good again, because they're
so untrained, so out of shape, if you will, that they feel better. They can train more.
They can train harder.
They can recover faster because they have a Roman system.
So that caveat aside, rest.
I remember when I was in high school, the gym I worked out in, which was a powerlifting
gym, which is why I got into it, but really my primary goal was training for boxing.
So I was doing infinitely more volume.
And the powerlifters, they would mainly train in the evening.
So I think it was Tuesday, Friday evenings or something. It's exactly as you described. First of all, the two things
that stand out to me even to this day, you know, 50 years later, I'm being a bit facetious. It was
only 32 years ago. One is the obvious. How incredibly and insanely strong these men were. And two,
was how little they did. I couldn't believe how little they did. They would come in, they would
put their slippers on, put their suits on, chalk up, do a set, rest for what seemed like an hour,
do another set, rest for what seemed like an hour, do another set, and leave. And admittedly,
they were lifting cars in there. They were so damn strong. But I just
remember thinking like, how can you do so little? But I think you're answering that question.
In what they were doing, that's every single match has to go into burning for that flame.
Has to. Let me think about this. You're trying to put a thousand pounds on your back. There's just no
room for a percentage of fatigue. There's nothing. I mean, it's consequences are quite dire here.
I'll think about this way. Even though, say, a thousand pounds represents one, they're one
right max. It's a hundred percent. And you could do 250 pounds and that's your one right max.
This is not the same thing. It's not the same thing, because even though it's both 100% of your wonder max,
there's an absolute load that is on a physical human body
that is not, does not scale.
And so like there is a major difference.
That's right, the connective tissue
is not scaling mainly at all here, right?
They still have tendons and bones
that are not that much different from mine.
Correct, they're a little bit, but not that much different. And so when they go do that, they're not that much different from mine. Correct. They're a little bit, but not that much different.
And so when they go do that-
They're not so correct, different.
Yeah, when they go do their heavy squat day,
or their deadlift day, remember,
if they can squat a thousand pounds,
do you know what they're doing for 70%?
That's a 700 pound squat day.
And so like, those are their light reps.
Those are their maintenance reps.
So that load is, it just takes so much more rest than when
you do your 70% and you can come back tomorrow and squat and be fine because it was 220 pounds.
So that relativiveness doesn't scale. Even if you're talking about people that aren't like
crazy strong, let's say they're a 700 pound squatter. That's still absurdly heavy. Their practice
reps are 520 pounds. That says a ton of load on a human body and that takes a lot to recover from.
20 pounds. That's just a ton of load on a human body. And that takes a lot to recover from. Before we go on to the Olympic weight lifter, let's pause for a moment here and just ask the question,
what do you think is the long-term consequence in a power lifter? Is it the case that, look,
if your mechanics are great, you can live a perfectly long, healthy life that is free of orthopedic
disability in the final decade of your life. Or do you believe that at some point
if you're really putting 500 plus pounds on your back repeatedly, the
probability of injury is high enough. And I don't mean acute injury. I just
mean the chronic wear and tear. You know what? The likelihood that you're going to
make it into the last decade of your life without significant limitations brought on by either spine or
joint injury are pretty high.
What's your take on that having watched a number of athletes go through this?
So scientifically, we don't have really any data to speak of.
So this is all anecdotal.
I just don't have enough to walk on that.
I don't think you would find a very highly competitive powerlifter who is under the illusion that this is great for their
health. That's just not a thing really. And they sort of either ignored or accepted.
Having said that, I can name you a ton of people who feel fine. You know, world record holders,
multiple world records or close. I can name you a ton of people who just lift kind of
recreationally in the gym, who are all beat to hell too. So it's a little bit of, well, okay,
I can find examples on both sides here.
It depends on how they train.
And because we don't have randomization,
we don't know if the people who are just doing great
would be doing great no matter what they did,
and the people who are all beat up to hell
are gonna be beat up regardless of what they do.
And there's also a little bit of insanity.
So you have the people like Louis Simmons.
And you're like, well, okay,
two trained with a broken back,
a known broken bone in your back.
So I don't even count you guys.
That's not the normal response.
If you're trying to break world records
all those people are training hurt.
I can say the same thing about professional fighters.
It's a hurt sport.
But then I could tell you a bunch of them
who are wrecked their whole life afterwards
and then a bunch that are like, feel okay.
It's hard to say.
I'll put it this way.
You take any sport, you take cycling, you take swimming
and you push it to the extremes like that.
I mean, you're asking not to be able to use your shoulders
best of your life.
So it's not the sport per se, it's the extremity
and really that I think is aidation. I completely agree. Anything you want to add to the training requirements of this
athlete before we move on to weightlifters? I could, but just in a second time, let's...
We've covered the big stuff. Okay. Remind people what Olympic weightlifting is. Again, the
nomenclature here gets very unhelpful, but why is it that these are probably among the most powerful athletes in the world?
Sure. So this is now similar to a powerlifting. This is what most people think of when they think of powerlifting.
And that's because they're going to do two exercises. One of them is called the power clean.
So I have great sympathy for you people who get all these confused.
The difference here is similarly to powerlifting.
Olympic weightlifting is a competition of who can lift the most amount of weight one time.
That's it, right?
There are two exercises, one's called the snatch, one's called the clean and jerk, the clean
jerk has two parts, so that's sort of two names, but it's one exercise in competition.
Whoever lifts the most snatch, whoever lifts the most of the clean and jerk, you have those
two up and that's who gets our gold medal.
It's one rep, you're your best score and one rep edition, and it's the most amount of weight you can put in the bar.
That's it. The difference is that why is this not powerlifting?
Why is this not truly a maximum strength test?
It's because both movements require you to take the bar from the ground and throw it over your head and catch it.
Because you're doing that, there is a speed requirement that has to happen.
You simply can't throw a maximum weight over your head and catch it. Because you're doing that, there is a speed requirement that has to happen. You simply can't throw a maximum weight over your head and catch it slowly. You can absolutely
deadlift slowly. It doesn't really matter. You can bench slow and you can squat slow.
You don't want to try to go fast, but it is not required anything. So if you look at the
sport of power lifting, and in order to take a, especially a snatch, which is apples to
apples, these snatch is the single highest power producing exercise that has ever been studied.
So nothing else produces more power per exercise than a snatch.
And that's because you have to take the bar from the ground and throw it over your head
and try to catch it.
You just can't do it slowly.
Your feet get to leave the ground so you don't have to worry about staying in contact.
But the bar doesn't crash down on you, like if you do the speed squat and jump and you
jump from the other bar, but it's smashing you in the back of your neck and your head
and that hurts.
Bench press, you can't accelerate through the end of the range of motion because the bar
would leave you, so you actually decelerate towards the end of the bench.
Anything where you're holding on to the implement, it's going to slow down.
Things like throwing a medicine ball are great and they are very powerful, but they're
not as powerful as a snatch because the load gets so low.
So let's remember, power is force times velocity.
So a medicine ball throws a high velocity, but it's a 6 or 8 or maybe 20 pound ball.
With a snatch, you might have 300 pounds on there.
You might have 100 pounds.
It's just a lot heavier, so the force can go on its higher, so the power output is significantly higher. It is the best way to produce force, so because of that,
those athletes are, again, quote unquote, the most powerful, because they're doing the most powerful
movement. So if you were to look at like the vertical jump height on these individuals,
it's absurd how high they can jump while still being exceptionally strong. So you're still
talking about people who aren't squatting a thousand pounds,
but at the same weight, they might be squatting seven
or eight hundred nine hundred pounds.
And also they're doing it at a speed
that's not as high as, say they're not jumping as high
as like a basketball player,
but they're doing it with 600 pounds, 400 pounds, 500 pounds.
So that's why it is, quote unquote, more powerful.
So you could find higher jumpers,
you could find higher squatters, but they have this wonderful
combination of really strong and really fast.
And that's why they produce so much power.
Now, going back to what we said earlier, they have to be strong.
And so presumably, they still have to follow the exact same principles we just talked about
for strength.
They're not going to optimize their strength doing 12 reps.
They're going to have to be in sub five.
I guess here my question is same thing, right?
We've got the same avatar as you describe it.
The middle-aged woman now, let's just say,
who was an athlete in college and wants to try a new sport.
This is the sport she wants to do.
She's trained, she's not a stranger to exercise,
but she's never done weightlifting, meaning the not a stranger to exercise, but she's never
done weightlifting, meaning the Olympic weightlifting. She's never done these two movements.
I'm assuming that you're doing a lot of the movement learning with very light load. You're
doing a broomstick, perhaps the first time you do a clean and jerk or a snatch.
Totally. How is she training her strength in those movements?
When you talk about Olympic weightlifting or weightlifting,
of all the things we're going to talk about,
this is by far the most technical component.
And so we have to, I'm going to almost
kind of leave that part of the conversation.
We're just going to get bogged down there.
But we do acknowledge it, right?
It is a ton of technical work to get there.
Because your point is right, if you are simply
snatching a PVC pipe, you're not
going to generate any strength that's pretty easy to understand. You're not even going
to produce any power really because the load is way too light. It's super fast. It's honestly
hard. You can't actually throw a PVC pipe, but you're having very fast. It's very awkward. Trust
me. You can't jerk it over. I get super awkward. So once the technical component is sort of acquired,
what you would have to do to answer your question is build the technical skills and then get strength
of acquire. What you would have to do to answer your question is build the technical skills and then get strength doing a say a front squat and doing a push press or an overhead press
or something like that. More traditional why you're building the technical ability because
what's going to happen is you won't have the technical ability to even get heavy enough on this
matching plan and jerk for quite some time because you're going to be so limited by technique
rather than strength or speed. So that's going to hold you back for a long time, because you're going to be so limited by technique, rather than strength or speed.
So that's going to hold you back for a long time.
And this is why a lot of folks will frankly not use these movements, which I think is a mistake.
But if you were the classic kind of personal trainer, and you know, you got a client coming in once a week,
cheese, are you really going to invest three months in a teaching minus match before they actually burn a calories,
gaining muscle, or get stronger? Well, it's probably a losing endeavor.
But if you have somebody for a year,
more importantly, how somebody says,
I'm committed to doing this, I'm gonna invest, okay,
five years, 10 years, this type of stuff,
then it's probably worth while endeavor there
because it is total body.
It's a deadlift, mixed with a vertical jump,
mixed with an overhead press and a catch,
mixed with an overhead squat, you're moving, you're jumping up and then down, and then
you're catching yourself.
So balance and proprioception are also there.
Your lats are going to go to keep your position in the back, core has to be there, then
overhead squat it.
It's very, very well rounded.
With the exception of horizontal pressing, it covers just about everything else.
And so it's a very economical movement. And also, it's peak concentric and eccentric,
because the amount of deceleration you have to do in that movement is insane.
Whereas, for example, in powerlifting,
you don't really get to test the eccentric phase to the same extent.
Yep, there's no landing, there's no absorption,
and there's no movement in space,
which is very important for
neural control brain, keeping your brain healthy and everything like that, catching yourself in a fall.
So yeah, super productive. My brother at one point became obsessed with setting his school record
when he was in law school and he had a year of eligibility left. So he played football for another year.
And for some reason, one of the tests that they were putting the team through was like a clean and jerk and he won I forget how much he moved it was a lot for he was about 185 pounds and it was about twice his body weight or close to it
But here's what was interesting and it what you said is what reminded me of this all he did was the following to train
He would put 135 on the bar as the max amount and do that as perfectly and quickly as possible.
You know, he would be filming himself, making sure Elbow, you know, bar travel was perfectly straight
and then do insanely heavy front squats and shrugs and all sorts of other accessory movements.
And then on the day of the competition, he just went up, they've got three and a half plates on the bar
and he just did it that one time and that was it. But he never had trained above 135.
I was amazed by that,
but it sounds like that's not an unreasonable strategy here.
Yeah, it wouldn't be my strategy.
It wouldn't at all, but in his perspective,
I mean, you would have pushed more in training
higher and higher weight,
but he got kind of lucky, I guess.
It worked for him.
No, I wouldn't say that.
I would say this.
Let's say he did, he's 1805 pounds,
and let's say he did...
350 or something,
it was probably around 350.
350, great.
Okay.
He probably could front squat 450 at that time.
It was probably back squat in 500, I don't know.
He was probably so limited by his technique,
though, rather than his strength,
it was a smart idea to invest a lot in technical proficiency.
So that's probably why he got so many more strides in technique,
because that was so far behind in terms of the two things
you have to have to do that moment.
You have to have technique, and then you have to have horsepower.
He had way more horsepower than he had technique,
so he invested heavy there.
And that's probably why he would have got away for it.
To give you some numbers here, like we do with powerlifting,
if you want to look at a good cleanser,
like a really good one at the lower weight classes,
triple body weight is where we're after.
Triple body weight. Oh my God. Now, this, and this doesn't scale with size. So if you
look at like Lasha, that the best guy in the planet for the last six or eight years,
the kind of the number we always throw over there is like 265, that'd be kilos. So like
five, I think that's five, 70, ish, range, something like that. But he probably weighs 350.
So like if you're 350 pounds,
you're never going to double body weight. Sorry, 585, like 585 is the pounds. No one's ever...
But the guys that are like 140 pounds can actually get to three times their body weight.
Yeah, for sure. For example, I was able to clean a jerk double body weight and that got me like
seventh in the nation. Now it wouldn't get you to the
competition, not even close. You want to get to a national level competition as a male
you're probably doing, you know, certainly double body weight, two to and a half. You
want to like place internationally probably much closer to that three. There's not a lot
of people who do triple just to be clear. There's not a lot.
So how are we going to train this woman now? So it sounds to me like we're not going to load her up on the clean and jerk and on the snatch.
She's going to be using more weight than a PVC pipe and an empty bar, but we're using 10 pound bumpers for most of the time here until we get that working just right.
How are you training her strength so that you're building up the horse power to match the technique you're building.
ranked so that you're building up the horsepower to match the technique you're building. I know how we're doing it in terms of reps and sets based on the three to five.
What exercises are you doing to most meet the needs of what she's ultimately going to
do when her technique is good enough?
So think about it this way.
If you look at peak power production, what I say this, you take the force, so how much
load is on the bar and you take the, and we plot it against each other. At some point, if it's too light, but very, very heavy, it's not powerful. Opposite,
and in the spectrum, same thing happens. So the question is, where is that crossover point,
which there's enough power, or there's enough velocity and enough mass? Well, this is actually
hyper-specific to the exercise. And since we're on the power, the weight lift theorem,
kind of getting on power, if you do an exercise like a bench press or even like a tricep extension, that's probably going
to happen at somewhere like 30 to 40% of your 1-rat max.
You'll have peak power, so if you can bench press 200 pounds and you want to train power
on the bench press, you should probably put 80 pounds on the bar, something like that 30%.
If you move up to a more compound movement, like a squat, instead of being at 30 to 40%,
it's more like 40 to 50% for most people of your peak.
So if you're again, if your max is 200 pounds in the squat, maybe you put 100 pounds in.
If you go to a cleanser or a snatch, that number gets much higher to like 80 to 90%.
So a lot of folks won't hit peak power in a snatch until they get to like 90% of their
1R max.
If you do 90% of your 1R max on a bench plus, you are going to be moving super slow and you will not be producing
any power. So the optimal number, and by the way, the more trained you are, the more that
curve it's shifted to the right. So you can produce more power at a higher load relative
load. The how heavy to put it on the bar to maximize power is very dependent upon the
movement. In the question, you ask like, how are you gonna get this person stronger?
It's not gonna come from these exercises
if that's the technical limitation.
You may have to get a kettlebell
and do like a heavy kettlebell swing.
Maybe you wanna do an RDL.
Maybe it deadlift.
Maybe a step up, any number of exercises like that,
until they can get to a technical proficiency,
do where they can get 50, 60, 70% or probably even higher,
then you're not really going to be truly testing strength because you're still going to be
super limited by technique, because you're not even at the peak power yet.
And you'd put, again, just going back to that.
That's super interesting and I've never thought of it through the lens of how that varies
so much by exercise.
But bench press, tricep press down, maybe bicep curl, you're going to hit peak power lower in that range. 30 to 40%. Super low low. Yeah. You go to a leg
press or squat or deadlift, you're 40 to 50. Depending on the person, yep. Percent of 1RM.
And once you move to something so insanely technical, you've got to get close to 80, maybe even
90% of 1RM. Yeah. And that's because of the nature of the exercise.
You get to explode.
And it's what we call a triple extension, right?
So it's an explosive hip, knee, and ankle extension there.
It's going to be so limited by the skill that you got to go having before you're getting
the peak power, let alone peak strength.
Last year I swapped out my leg press machine for one of the Kaiser ones.
So it's the, you know, pneumatic device.
And I love it because it's giving me power by rep.
And it's so funny.
Now I haven't been able to figure out the exact formula for max power, but that's generally
what I'm trying to hit, right?
I usually use power as the metric I'm training to.
And then I look at the fall off and fatigue.
So now I'm going to pay more attention to that, which is am I truly hitting peak power
at, I mean, I 50% of 1 RM and that kind of stuff.
So that's so cool.
I can't wait.
If you're pretty trained, you might
be closer to 60%.
And is it like a front squat machine?
The Kaiser McLean is the seeded like this machine.
It's like, oh, yeah, you might be higher.
You probably be somewhere in that range.
Kind of just depends.
I'll look for that.
That's cool.
That's where here, 20 plus years ago,
I was in a facility training professional athletes.
And we had some of those machines. And I went probably personally, I was in a facility training professional athletes and we had some of those machines and I went probably
Personally, I don't know six maybe eight weeks straight
Just using that Kaiser machine and all I did for training was try to hit the highest watt output
I could do didn't care how many reps it took didn't care how many sets I would take a break
I would rest I'll try it again and I would go until I got a higher number come come back the next week, and I went up for eight weeks just by trying to optimize power output.
The thing you talked about earlier, the velocity transducer, there's another way of training
here for strength or for power that is velocity based training, which is almost exactly what
we're talking about, which is instead of worrying about the weight or the rep ranges, we're
simply trying to hit the largest power output possible.
We're going to do as many reps as we can there with brakes. And that's how we're going to
maximize power output. It's a very, very effective method rather than just putting an arbitrary
number of reps down. You're going to go peak power output. That's sort of how I use the device now,
right, which is I say, for this load, I should be this many meters per second. And when I can't do that twice consecutively, the set's over.
And sometimes that means the set ends at five.
And sometimes that means the set ends at eight.
But you agree that, and I don't know, this sort of stems from my belief,
which might be totally unfounded that I'm quote unquote,
sort of wasting reps.
If I'd be better off resting and coming back and doing it again faster and harder
in three minutes, then eking out more slow reps. Is there any validity to that?
Oh, it's not unfounded at all. There's strong science on that. Brian Mann at the University of
Miami has done a ton of great stuff on velocity based training. You could check out a lot of his work.
But there's a training concept called cluster sets. And so cluster has been shown to be
highly effective for strength, power, and even
hypertrophy, surprising enough. But what a cluster is is this. Let's say you were going
to do six repetitions in your set. Let's say five, just keep it consistent. Five reps.
You could do, we have one, two, three, four, five, no breaks in between. Or a cluster set
says you're going to do one rep. You're going to take a five to 20 second rest. You'll
do the next rep, five to 20, five to 25 to 20. So you're still doing quote unquote five, but you might
accumulate a, but you have micro breaks, micro breaks. That's what clusters are. And they
are extremely effective because they do exactly what you just mentioned, the quality. And
when I bite by quality here, I mean power output, velocity output, et cetera, it goes up because you reduce fatigue
and specifically reps three, four, and five. Those will be much higher quality. So the
old way we would say it is, instead of getting five reps, you get five first reps, which is
much more important, right? So you get five higher quality ones. So the aggregate quality,
force output total achieved, velocity, whatever is much higher.
So it's very, very effective.
Now, it's funny is weight lift or Olympic weight lifters have done this naturally for 50
years.
So when they do a set of like, say, triples of a clean or a snatch, no one ever goes, boom,
boom, boom, you drop it, kind of reset, shake your hands, re grip, take a breath, reset,
and it takes five to ten seconds and you do.
So your three reps, like, takes a minute. Here's like PR triple. It's like, you got a sandwich in
between reps. It's not a triple. Like, what are you doing?
You just need to email between those two.
You're not pure double. You did two sets of one. But there's a reason. Now, it may not be optimal for
other. It may not be optimal for hypertrophy, it may not be optimal for other. May not be optimal for hypertrophy, may not be optimal for pure strength,
but here we're talking about the most powerful movement.
Super effective for pure strength.
Super effective.
It is.
So just to be clear,
would you even advocate this,
if you're trying to increase your deadlift,
do you think it,
if you're saying I'm gonna do five reps on this deadlift,
you would actually say it might be better to do five ones
with 10 second break in between.
If you're going for pure strength, no doubt about it. Good research on that.
Okay, so that's super interesting to know.
Again, the little caveat here, we're getting a little deep.
Exactly like what your coach said earlier. What was the goal here?
Because if the goal was pure, pure, pure strength, great. If the gear was though,
like some strength, but we need to accumulate...
With a bit of muscular endurance.
Then you would not maybe not want to take that break. So everything matters.
I guess I was going to say it so.
I love that by the way.
It's just like, what was the goal here?
That's like the best coaching thing ever.
Like, what are we trying to do here today?
It's a great coaching advice.
Suffer.
So how often do you want this woman in the gym?
So here's the fun part.
Oh, this is really good.
Because the total load is low, you can do this every day.
Right? You're talking about a small number of reps, not to fatigue, not at all to fatigue.
You're talking about a lightweight. You can go every day. There's no reason why you couldn't go do
some power training, pick any power sports, basketball. Yeah, it was just about to say, this is no
different than saying I'm going to go play basketball every day. It's better because there's
even less fatigue than because there's a lot of fatigue in a basketball game.
So as long as you keep these high quality,
now if you are doing these two fatigues,
set to 20, five seconds rest in between,
then that's the whole different thing.
But if you're doing these non-fatiguing,
which is what you need to have for power and skill.
So this is a very important point.
For power and skill development,
they need to be non-fatiguing.
If you're getting to fatigue,
you're not doing either one of those things.
Now you can get to fatigue if you're trying to produce
a different adaptation, which is maintenance of power through fatigue, you're not doing either one of those things. Now, you can get to fatigue if you're trying to produce a different adaptation,
which is maintenance of power through fatigue, which is fine, but that's not the same thing.
You're not going to improve your peak power by fatigue. It doesn't happen.
So, these sessions are kind of like, quote unquote boring. You're not going to get a big sweat,
you're not going to get a big palm, you're not going to throw up in the floor afterwards.
It's sort of like, okay, and you go home, like damn.
And this is honestly why they're generally not very popular.
Like I got powerful, but I don't look any different,
I'm losing weight, I don't have any of these other feedback
mechanisms that suggest I got a good workout in.
Despite the fact, it is very high quality training,
you just not get that feedback.
So in power training, power development stuff,
very, very low fatigue, that's the goal.
Which type of athletes that are not weight lifters do you have doing these exercises?
Oh, basically everyone.
It's hard to pick a sport where power development is not important.
Cavia's here.
If you're a heavy weight champion, a bellator, you're a professional EOC fighter.
Am I throwing maximum weight over your head and catching it all the time?
I wouldn't hesitate to do it, but a lot of times they just simply have problem.
Not gonna happen.
I don't hesitate to do it with professional baseball players.
Don't hesitate to do it with pitchers, though many of them don't have shoulder without
getting too technical.
Your shoulder needs to slide and move in a very specific way, especially when you're pitching.
And if they don't have that, then we would walk away from this.
Or if they don't want to, it's fine.
You can get away from it. And then that football player,
wrestlers, skiers, tennis players, saying, if you're a shoulder athlete and you have any number
of reasons you don't want to, great, we could walk away from it. But there's really,
anyone else can really go after these things. If it's all done appropriately, it's a fantastic
exercise or set of exercises, rather. I want to talk about something that ties into both weightlifting and powerlifting
that I used to do.
I don't remember if it was just bro science, but empirically, it seemed to be true.
I used to have this set that I really enjoyed doing.
So it was a heavy deadlift.
So it was either a two, three or four rep deadlift.
And it was supersetted with,
I'm trying to think,
could I do it as a jump, plyo, or a drop?
But basically, it was a plyometric in between.
And the empirical observation was both helped each other.
So it doesn't sound like that should be the case.
It doesn't sound like my rest between deadlifts
are plyometrics, but yet it did seem to make
me stronger.
Now maybe that was psychological, but there was a sort of broscience belief I had that
that was doing something to the muscle fiber to get it ready to lift heavy.
It sounds like there might be some validity here.
No, there's a lot of signs here.
So what you're referring to is a phenomenon we call post activation, potentiation.
That's right.
Post activation potential.
It went around for a long time, very classic
Elbunheneman size principle.
So 1950s, 54, 56, 58, sort of a series of papers back then.
But basically, remember her in the conversation
we talked about fast twitch and slow twitch fibers?
Well, there are things called motor units.
So when a nerve comes down and goes into a muscle,
it has a whole bunch of muscle fibers in that.
So the nerve and all the fibers collected together
is called the motor unit.
All of the fibers in that motor unit
are the same fiber type.
So all the faster it's ones, all the slower it's ones,
whatever, and these are spread throughout the muscle.
So what happens is when you do low velocity movement
like right now, I'm doing all these things,
I'm using low threshold motor units.
And these tend to be slow twitch
ones. So it makes sense if I go to scratch my eyeball, I don't want to be producing max force
and it's not a good strategy, right? The best strategy is you start with the lowest force output
humanly possible and then you work your way up and that's because this principal and other
one called all are none, which means when a muscle fiber contracts, it contracts with a hundred percent effort, you can't regulate it up and down.
There's no dimmer switch.
It goes on off, on off.
So the only way you regulate force production is to increase or decrease the total amount
of motor units that are activated.
Because when you activate a motor unit, all the fibers get activated and all of them
get activated at a hundred percent contraction.
So what happens is, I go to scratch my eyeball and I
activate the motor units that are the smallest and weakest. It's not necessarily like that, but it's
proof of concept here. And now I realize, oh, I'm not scratching my eyeball this time, now I'm actually
picking up a medicine ball. Okay, I'll activate those same initial motor units and I'll activate
some other ones and some more ones. And then I realize I'm not picking up a medicine ball and picking
up a car off the ground. Now I'll activate more and more and more and more and more of these higher
threshold motor units. So those tend to be the more the fast switch fibers. So in the case,
the post activation, what's happening is you're doing that deadlift. I think you said deadlift
in an applied- Deadlift in a bio- You do that deadlift. And because the size principle and you're
requiring force production, you are activating higher threshold motor units.
Then when you put the barbell down and you go to do your jump, those are still engaged and activated.
So now you can actually jump with more force and velocity because you've sort of turned them on.
Initially, you've activated them.
And so it's 100% and there's a lot of science Lee Brown, who's lab, brought me over to Cal State Fullerton, has done Legendary, he's a lifetime achievement
award winner, Legendary work in this area.
You can also go the other way.
So this is fun.
When it comes to power training or speed training,
people tend to think about things like resistance.
So in other words, if you've ever done sprinting
and you've like drug a sled or had a parachute on,
great, you've done vertical jump training
and you've had like the bands that hold you down. This is all added resistance. And that's fine for teaching you
acceleration, which is moving over inertia quickly. However, the other side of the equation
is if you want to get fast, I'm sort of jumping the gun here, we're kind of moving into
our speed one, but it's fun, right? You actually want to also practice moving faster than you
can currently move. This
is what we call over. Yeah, I had a friend who was a sprinter in college and they would
do downhill sprints, like they would do 40 yard dash down an incline of 6%. 6 is pretty
aggressive. Either way, it's over speed. Maybe it was four. It was like basically their legs
were turning over at a speed that they would normally not even be used to turning over.
Yep. So instead of dragging the parachute, you turn around on how the bungee cord pull you
a little bit, or you run downhill, or you do something with, we actually had a device
in our lab that is a harness that came down to you, and we could reduce your body weight
by 5, 10, 15, or 20 percent, and you could do all your vertical jump training, which we
did with the volleyball team for one semester.
And you're jumping higher than you've ever jumped.
So it's the same back sort of post activation, or PAP, in reverse. So you're actually learning
to move faster than you could possibly move. So then when you go to actually do your work,
and you move faster. And the best example of this with Lee's work was you've seen baseball players
swing a baseball bat. And before they go up to play or they go up to their bat,
a lot of times they'll put it what's called a donut.
That weighted thing on it.
Yeah, donut on it, right?
And so you swing that thing, it feels heavy,
and you take it off and your baseball bat feels light.
And that's great, awesome.
Well, he actually looked at whether or not
if you swing a wiffle ball bat.
So this is a plastic bat super light,
which you can swing really, really, really fast,
prior to that actually improved baseball bat velocity
more so than the donut did.
So PAP, that's the donut.
Great, super effective, but also unloaded super super fast is equally effective as well,
I get you. So if you want to maximize, you probably should play with a little bit of both in the
spectrum. You can do this with bands and chains, like a lot of the times we'll do, it's take like a
heavy band that you would deadlift with, and you can put on any of your lats and hook it to a
thing above you and you could do assisted vertical your lats and hook it to a thing above you,
and you can do assisted vertical jump training and just start flying and lots of other ways you can do it.
Yeah, that's a very real phenomenon, and the reason I brought that up is because you mentioned
you felt like the dead lifts helped the plio, and I explained to you, it did.
They both seem to make it. But that's the point. So the plio helped the deadlift because of the
overspeed thing. This is called complex training,
not complex as in like multiple body parts and things like.
Complicated.
And not a complex as in like a stack of different exercises,
which is kind of a different term here.
So there's a different kind of strategy you can do
called contrast training,
but this specifically your first like a complex
where you would do, if you're gonna do this,
you need to stick with them the same principles. So your total reps per set should still be around three to five. So in other
words, you could do like two dead lifts and then three vertical jumps. Or whatever, but don't do
five dead lifts and then five vertical jumps. Your total set is not like 10. You're certain to fatigue.
Yeah, you can do this all kinds of ways. So we'll do this bench press and then medicine,
malt, plush or rotational movements. Tons. I mean, the thought that I had at the time was this is so ridiculous, but why does a sprinter
not 30 seconds a minute before they hit the blocks do a heavy set of three deadlifts?
Well, the first one they do.
Do they?
Oh, okay.
When they can't, okay.
The reason why they don't see it as often is because logistically, you have to have a
bunch of dumb-up barbs.
Yeah, yeah, yeah.
It's not uncommon, depending on what facility they're in,
they'll be in the back, they'll hit those edges
and then they'll walk right out and going.
And you gotta put your spikes on all that stuff.
Yeah, it was just so counterintuitive, right?
Yeah, so you can't do this,
and then an hour and a half later,
go around and go faster.
So you have a window, you can do it in,
you get your spikes, and like,
so there's some like the logistic things,
but it's very common to training,
when it sees you to weigh with,
so it's super, super effective.
Let's move on to strong man. We don't have to focus specifically on like an actual strong
man competition, but maybe focus on feats of strength that also tend to require a lot
of stamina. I don't know. Would the classic strong man activity be like an enormous sled
pull or something like that, pulling a truck, picking
up a barrel and throwing it and walking over and picking it up again and throwing it.
I mean, there's a lot I can think of.
My favorite was tire flipping.
There was a 450 pound tire the Gemma used to belong to and how long it would take you
to do 25 flips was a metric of your.
I love it.
Yeah.
Farmers carries tons of wrote pulls, all kinds of good stuff.
Yeah.
Now we're starting to get from highly, highly specific where powerlifter, you've
got three things, weightlifter, you've got two things. Now we're really getting into more
breadth. There's almost no limit to what a quote unquote strong man, strong woman can
do. And maybe one would argue, this is more functional, this is more versatile, this is more engaging,
you're also probably not starting to expand the interest of the GenPOP into what we're talking about.
So, you at the outset said the three things that mattered most were specificity, specificity,
and specificity. When you're dealing with something that has so many components, how do you wrap your mind around specificity versus generality?
Yeah, so this is why Strongman is great.
I mean, probably like you a little bit.
One of the reasons I got in this field is because of the Strongman being played
on ESPN at three in the morning, in the 1990s.
Thank you, Bill Kazmer, like this is a whole generation of us who like,
what is this stuff? This is incredible, right?
So there is still some specificity, like when you get to those competitions because you kind of know
which you're gonna do. But yeah, this is why they're dope, right? Like someone who's optimized for
grip strength, you know, hold the Atlas stones or something. It's not gonna be the person who's
optimized for the deadlift carry, the deadlift competition or the the overhead press or whatever,
right? You'll see people who win three straight events and then they'll get deadlast in another one.
CrossFit has a very similar feel here. So we're going to test you in a month to different planes
here. And if you're great at deadlifting, you're probably going to be poor at pressing.
That's just sort of how it goes. Right? So in this particular case, you have real strong
man, who are in fact, based on the definitions we said earlier, not technically, quote,
unquote, the strongest in the world. Because the way you win in strong man or woman is how many reps
typically can you do at a very heavy load. It's a global fetus strength, but it's not to the same
level of high precision. So if you were to then technically take everyone from a strong woman
competition in the same way class as everyone from the same equivalent level of powerlifting competition,
the squat would probably be higher on aggregate and the power lifting competition. However, if you said let's put on 95% of your one-on-a-max and see how many reps
you could do, the strong one would absolutely smash. Again, on aggregate. You could pick one
individual perverson or something, but as an average. And so what we're doing here is saying,
we're going to take extremely heavy loads and we're going to ask you to do it to fatigue.
But we're probably going gonna do a little bit safer
than we would typically do.
So you don't generally see like a bench press to fatigue
on a strong man.
You don't see a dead lift to fatigue often.
You're gonna see something like a car lift.
And the reason they do that is because you can actually
load the bar a lot higher in the air.
And so it ends up being almost closer to like an RDL.
So you take that knee cross out of it
and allows you to do a lot more reps.
It's still brutal, still like insane. That's what I do some funky stuff like that. A farmer's
carry. You can do that as heavy as possible and drop it when you're done. To kind of hedge
in that direction. Same thing you why you would never see a snatch or a clanderc way way way too risky.
It's going to be a log press overhead awkward and weird but and that's why like even the tire flip, like I remember people would say, like, come on,
how can you flip a tire of this 450 pounds?
And it's like, well, remember, you're never fully lifting a 450 pound thing off the ground.
Like when the first movement of the deadlift, it might be 250 pounds that you're lifting up.
And then by the time you're pushing it, you've got the momentum helping you.
So yes, it's infinitely safer. And ultimately, you're fatiguing, at least for me, my cardio respiratory and muscular
fatigue hit almost at the same time. 100%. You're going to feel blown up. Your forms
have been gone. In fact, you know, it's actually really cool is maybe five or six years ago,
they started putting heart rate monitors on people in these competitions and then they'll broadcast
them. They're just pegged the whole time.
They're like 180.
The entire time.
Max heart rate.
It's lovely.
It's true.
Which is actually one of the, another reason why one could argue if you wanted to look at
something that is generally better for global health, it's a pretty good endeavor here.
You're going to get a lot.
It is human movement.
It is varied.
It requires stabilization and all kinds of random movements, but it is super
heavy and to the high levels of tea.
So yeah, it's a great moment.
So now let's talk about this one again through the training of a person who is new to this.
So guy comes to you and he's never power lifted.
He's never weight lifted.
He's never done a strong man.
He goes to the gym to
do a little bit of cardio and do a little bit of strength training, but there's never been
specificity to the training. He doesn't have any injuries that we need to worry about. Let's just
put that in there at the moment. So there's nothing that's truly off limits, but he has no technique.
He's not coming in on a foundation of he knows what it's like to deadlift at least twice his body weight or something like that.
It's just him he doesn't have that.
But he says, Andy, I'm interested in this both
because I think it would be a fun competition to do.
But also, I think it's more in line with my long-term health goals.
So I don't want to get injured.
I definitely do not want to get injured doing this.
And I want to be able to do it for quite some time.
Cool. So what you want to do is build a week,
a frequency, and what exercises you do throughout the week,
so that you are not doing too many things too often in the same
move matter. So for example, if you're going to work on your
farmer's carries, that's great today,
but you then probably want to work on a movement like a deadlift,
maybe the next day because you're going to be fatigued with your grip.
Okay, great. So then maybe you on a movement like a deadlift, maybe the next day, because you're going to be fatigued with your grip. Okay, great.
So then maybe you pick a non, maybe that's yolk lock or something like that the next day,
loaded up there.
So you just want to kind of be a little conscious of that.
How many days in a row are you hinging?
How many days in a row are you holding or pressing directly overhead and just kind of move or
vary the movement patterns is the first step I'd say.
Repetition range, I would probably stick in the like
five to eight window initially for this person
because you can get enough little fatigue.
You can also bail pretty easy.
It's heavy and you're practicing,
this is a big distinction.
You wanna practice perfect repetition.
And so what I mean by that is instead of going to like an RER
or RPE, I'm going to go
to technical failure. So we're going to do a goblist squat. We're going to do a hundred pound sandbag
or 150 pound medicine ball in front of you. And we're going to do front squats. And we're going to
do what the goal here is to do eight or so. But as soon as I see you break technical, you're done.
And that's going to get that person a lot of fatigue, a lot of strength, but also keeping them very, very safe
and they're gonna learn to feel,
I don't get to win anymore when I break technique.
So they're just gonna continue to learn
whole technique, whole technique, whole position.
And I would do the same for their overhead pressing,
all that stuff, right?
We start to get into bad positions than our low bat.
All right, we're done.
And so getting them to technical failure
is the phrase that we would use here,
is the way I'd go about it. And you can actually do these more frequently than the average same exact avatar could in powerlifting
because the movements are more varied. See, the recovery is probably going to be a little bit higher
rather than getting the same exact locked in position and just sort of moving in one plane.
You're going to get sore, but there's also not as much of a typically like eccentric landing
demand, like there is a weightlifting, there's eccentric but it's typically controlled or it's
intentionally unentcontrolled. So you can get away with more volume because your recovery is
going to be a little bit higher there. Tell me, going back to our weightlifter and power
lifter, why would we not also, or maybe we do and we just didn't state it explicitly? Why would we not also force technical failure into the mix?
Is there ever a time when we would tolerate a break in form where we see more lumbar
chyphosis or lordosis than we think is actually healthy, but we want to learn how to grit
through that because sometimes a single rep max sucks no matter what.
With the case of Olympic weightlifting,
it almost takes care of it for you.
So if you have a break in position,
you're probably gonna miss the lift.
So it's self limiting that way a little bit,
especially when you get past a certain load.
Like you could do 30% of your one or max
with very poor technique.
But as you start getting up higher and higher,
it becomes again a little bit more self limiting.
You definitely wanna make sure you're holding position
in all of them, but the technical demands of something like a little bit more self limiting. You definitely want to make sure you're only positioned in all of them,
but the technical demands of something like a bench press
are fairly low.
There's only a couple of joints
that really need to be taken care of.
As long as they're okay, you're there.
When you get into something like a snatch,
every joint has to be in the right spot
or you're in Kinga Lonkey,
a deadlift is the same thing,
like a deadlift is not as complicated.
A squat is fairly complicated though.
But there's also variations you're going to do, probably.
You're going to do some sort of box squat or chair squat.
You're going to limit the range of motion.
And so the last thing I want to say about that is, since the goal of powerlifting is to
achieve a one or a max, you're actually not trying to achieve optimal range of motion.
In fact, you go the opposite.
So physics-wise, work is forced multiplied by distance.
So if you're trying to maximize force, you minimize distance because you minimize the amount of work you have to do.
And so they are intentionally a limiting range of motion. So they're actually doing this like pseudo technique,
which is not to maximize actual human strength. It's to maximize the score on the barbell,
which is not necessarily the same thing. And so you're probably going to be working so hard
on that technique that it almost keeps you
out of the squirrely areas because you're trying to just,
instead of getting this like big, long range of motion things,
like you're just trying to get through the stuff.
You're going to go all the way down a touch,
but you're going to set yourself up in a position
that minimizes range of motion,
which is actually putting your joints in the right spot.
So it's a little bit there, take care of. What percentage of power lifters deadlift with a traditional narrow grip versus a...
I don't know an actual number there. Is that simply a leg length to arm length difference?
Like for me, Tsuma was so much more comfortable than narrow.
Generally, it's going to be. It just gets easier on the back. But it depends on three factors.
It depends on your shank to femur ratio.
It depends on your femur to upper back basically,
and then it depends on your arm.
So all three of those things get wonky,
and then it depends really on your hip versus backstrike.
So strong hips do well with sumo.
We hips are gonna get smashed with sumo.
A lot of ways you can go about it.
There's a whole argument we can have here,
but we'll probably skip it.
I'll save that for the next one.
Okay, so our strongman is training very frequently.
It's highly varied.
We're in more reps and we're training to technical failure,
meaning we're not pushing low-quality reps.
When we break technique, the set is over.
Okay, let me get from Jay.
The reason why I brought
technical failure up in this one is because you're doing a
combination of high load and high fatigue.
It's just too risky to break form.
If you break form a little bit and you're doing two reps,
okay, like the low is high, so that's the danger.
But now you're combining both danger, which is load and fatigue.
And so that's why like I were on the plant that distinction from
that avatar.
This is also an athlete who just talked to me about volume. How many hours a day are
they training? This is not the guy who's driving around Walmart for two hours trying to find
the parking spot. This person's fit. They're burning matches all day.
They're going to have to be to get to this kind of training. The no science here, you're
going to walk completely away from science unlike the previous ones. We could talk about
which we did get into number of reps in terms of total volume
to hit per month for like a weight lifter,
things like that.
You're gonna have any science on this
because like how do you quantify
holding a hundred pound medicine
on your chest and it's taking how many steps,
seeing how many steps you could take.
Like how do you quantify all these things?
If you do something like weight lifting,
and I can say how many reps did you do,
over 70% of your one-up max? And that's the number we're going to cause there's two exercises. It's
very easy. With this one, like, how do I equate time? How do I equate the fact that you
did one exercise and you did it for 40 yards with the other exercise you did it for seven
reps? I don't know. So I will give you basic progression recommendations here, which is
10%. So in general, regardless of physical exertion, if you increase your total volume by more
than 10% per week, you tend to start getting into problems.
That's the thing I would flag.
This is like, keep it below a 10% progression per week and start lower than you think and
then just add that up.
And again, how are we even thinking about going here?
It's not because in lifting, like,
I'm keeping a mental tally of sets and reps
per body part sort of thing or whatever, right?
How are you doing that with 100 pound medicine ball
for seven steps versus 50 pound medicine ball
for 25 steps?
They both heard about the same, what does that mean?
This is the problem we have in exercise science
comparing lifting to endurance.
How do I compare a three sets to 70% to 45 minutes at 65% of the O2 mat?
I don't know.
You have no comparator there.
This is sort of where in cycling, I'm sure you know, we use something called the TSS,
right, so the training stress score.
And then we have a chronic and acute training stress store. So as a cyclist, I used to have a dashboard, basically, that take the
data from my power meter. So every day I'd come in from my training and I'd
hook the power meter up to the computer. I'm sure this is not done via Bluetooth
now, but it would take a lot of data that was really relevant. So it knows a
couple of things about me. It knows my maximum heart rate, and it knows what's
called my FTP, my functional threshold
power, which is the highest number of wattage I can average for 60 minutes.
It's a super important number.
Everything as you know in cycling is metric on that FTP number.
When I come in from a ride, that ride might say, well Peter, you went and rode for three
and a half hours.
You utilized this many kilojoules
of energy. Your average power was this many watts, and your normalized power was this
many watts. And normalized power, it's a power function calculation that takes into account
the variability. So the more the normalized power is different from the average power,
the more up and down spiky you had. So normalized power gives you more of a physiologic sense
of what you did.
Well, these algorithms now were so good
when you had that data at telling you where you are
in terms of overtraining, under training.
And so if there was just some way we could get that
out of more complicated movements.
And again, I'm just thinking like obviously you could get that out of heart rate, you could probably get that out of more complicated movements. And again, I'm just thinking like obviously you
could get that out of heart rate, you could probably get that out of heart rate variability.
You could probably get that out of ventilation. So if there is some way to capture ventilatory
rate, but other than that, we're missing power. I mean, that's the bottom line is we just
don't have the metric for power. That output is what's making that, I guess, so difficult,
right? Yeah. In this particular case, you would jump to physiology.
You would go to THRB, certainly, like heart rate would probably
not be a great one, but you would have to go to what's
the physiological response rather than the actual metric,
which is one could argue better.
So like, who cares if you're at X amount of reps per week
if your physiology is fantastic?
The other thing is, I'm sure people who spend their career
coaching in this area probably have better answers for you.
If it was me coaching, I would go to physiology.
Like we're taking physiology metrics
and we're gonna see what happens.
Yeah, it's interesting.
I think one of the things we used to do
before we had our HRV to look at,
was look at resting heart rate in the morning
and look at, forget what the term was for it
but it was basically willingness to train.
Oh yeah, yeah.
Sounds silly but it turns out to be very highly correlated with burnout.
It still is.
Still like the single best metric you can take.
We only used a score of zero to three if I recall.
It wasn't like rocket science, right?
Yeah, yeah, it doesn't have to be crazy at all.
Like we will take this metric still to the day I die.
Yeah, there's manipulation that can happen there, of course.
And we always do something else, but it's going to tie very, very tightly
typically to even something like HRV.
Resting heart rate is okay.
It's just too slow, and the magnitude of change is too little.
And so HRV is much more sensitive that way.
You're not going to see a change in resting heart rate until you get far down the road.
Like, you're getting cooked here.
You can see them very quickly, matter of days, certainly within a week with HRV,
where you and Mayor may not necessarily see the hard rate.
But nonetheless, mood, how much you want to train,
any number of ways you're gonna ask that,
how do you feel today?
That's a good one, just like how do you feel today?
Don't give me any context, what do you mean feel?
No, no, just like how do you feel?
That's it, track that down,
and you're gonna see that thing.
In fact, you can actually do this,
we've done this with giant datasets.
That number alone, it's basically you're gonna run the same as HR as HIV over a big enough thing, like you're going to see the same
number the most part. So if you're working with like a big group of people and you don't
have a HRV, say middle school kids or something like that or people just ask that, again,
there'll be some outliers day to day and some scorrily people and all that, but you're
going to get a pretty good sense of.
Yeah, I mean, the takeaway here for someone listening is knowing how you feel the day of
and listening to how you feel the day of is really important.
If you do not feel like pushing yourself hard in the gym on a given day, that's a really
good sign that you shouldn't be.
You have to be a little bit careful here.
Say, sort of give it the warm-up.
Give it the warm-up phase and then make the decision before you get to the working sets.
Anyone who's ever, well, exercise knows plenty well.
Some of the days you feel awful are PR news.
You're going to eventually set a record that day.
And there's a little bit of like on the jaco scale of like, okay, like you just suck it
up, mental toughness, all that stuff.
But then there's also like, you don't want to just go nuts, you know?
But I would say just because you feel crappy doesn't mean you don't exercise that day.
It's a question of how hard are you pushing that day. There are days you're going to push and there are days you're not going to push.
I would argue there's no day you shouldn't be doing something. You've got to get through the warm
up phase before you make the distinction of whether it's a hard day or not. This is where auto regulation
training becomes so awesome. If you use things like say you have your velocity transducer and you know
that when you're at 50% you're typically at one meter per second, a
little more. And if all of your metrics are down, it's a pretty good indicator of like,
all right, this is not today. You feel terrible. You don't want to be there.
You're truly giving me an effort, but all the numbers are down.
Okay, we're back in the day. That's a nice way to do it.
Okay, let's talk about CrossFit. Obviously there's a pretty decent overlap between
CrossFit and Strongman and that CrossFit is there are events that take a really long time.
There are certain sets that can take 20 minutes that are metabolically as demanding as what
most people could barely do in an hour.
Health folks a little bit about how CrossFit works.
I don't know if we distinguish between CrossFit with a capital C and CrossFit with a little
C because there's a lot of CrossFit-like stuff that isn't maybe branded CrossFit, but I think for our purposes, let's just make it all
the same. Well, call it, and I don't mean this as any pejorative, but we'll just call it like
competitive circuit training and just anything like that. This is one actually thing that's really
cool about sports, is we get to invent new ones all the time, and we get to like continue to test
human capability in a lot of ways. It's really really really fun. So CrossFit is scored a little bit differently. It's a nice combination. There
are some weightlifting movements. So you might see one of the competitions being a one-run max snatch.
That's it. Well, thank you. Right. You might see it as like an endurance event. So you might have to
run a marathon or cycle a marathon or something like that, right. And then you might see some of
these more circuit training type of, you know, 20 kettlebell swings, plus three snatches,
plus a vertical jump, and 20 pull ups,
and many rounds of that, and you can do in 10 minutes,
you know, some things like that.
So the idea is you try to combine a bunch of these things,
and every event gets scored just like strong man,
and at the end of the three or days, or whatever it is,
whereas the highest amount of points, just like strong man.
So a similar strong man like that, it's not one of them,
it's not many, it's not one single structured exercise, it's a lot, it. So a similar strong men like that, it's not one of them, it's many. It's not one single structured exercise.
It's a lot, it's typically a combination of exercises
in the same exact one.
Similar to weight lifting and tech,
they'll use barbell movements.
It's typically big, complex movements and all that.
And it's similar to power lifting in terms of like,
hey, sometimes max strength matters.
So it's a little bit of like a combination of all these things.
So one thing that they do though,
if we compare this to strong man, is the absolute loads
are lower.
And so when you see a strong man, it's probably going to be doing something where the winner
of the competition might win with like five to fifteen reps.
Not always, but something like that, right?
So if it's a log press, you're probably not doing a hundred reps in a log press.
Some people might not even be able to press the log once or twice, and the winner typically
has five or six or ten or twelve reps.
Roughly here.
Crossfit competition volume tends to be way higher.
It is hundreds of repetitions per event sometimes.
And so what we've done is it's still very, very strong.
It's still very, very powerful, but it is less, you won't see anybody ever touch 600 pounds
in a cross-fit competition.
Every event in Strongman is 600 pounds plus.
You might see 1600 pounds.
It's way, way, way higher.
But you won't see Strongman ever reach 65 reps in an exercise.
It just never happens.
So it's hedge that way.
If you look at the avatar for a highly competitive male cross-fitter, 5, 9 to90 to 210 pounds. Strongest men, it's six six six two. It's three hundred
and thirty three hundred eighty four hundred like they're just so there's no
weight class in strong man. There's no weight class. Is there a weight class
in CrossFit? There are some weight classes in strong man now. It's kind of like
big medium little. Okay. And what about in CrossFit besides the gender
difference? Gender and age is the only distinction
that you have in those ones.
And I guess the reason CrossFit can get away with that
is you're gonna get punished the heavier you are
in some of the endurance events
and you're gonna get punished the lighter you are
in some of the strength events.
So the idea is that's probably why everybody
kind of coalesces around 200 pounds or 190 pounds.
The other part of it is they have a lot
of gymnastics space movements and a lot of hanging
and pulling things and you're gonna get hammered
if you're over 200 pounds and you have to do
100 pull ups in five minutes.
You're just gonna get crushed on that stuff.
Now CrossFit is wonderful and this is actually
a nice point to talk about another point.
If you were to take an elite athlete in any of these
categories, there's a misconception here
because I got a lot of, from our first conversation, a lot of people were like, oh my gosh, you're disregarding crossfitters.
They're VO2 maxes that relate. They're blah blah blah. I like, no, they're not. They're unbelievable
athletes. And they are way more cardiovascularly fifth and strong, man. And certainly way more than
pyrelyptores and weightlifters. But you're not going to find the average crossfitter that has the
same VO2 max as the average equivalently high-level cyclist, no chance. What you're misrepresenting
here is not that they have done something that we have never seen before. It's the fact
that they are just phenomenal athletes, like just absolutely phenomenal athletes. The
reason I'll say this is you know these numbers, better than I, you can bring me correct
me here, but if you were to take a high level cyclist, their peak power is astronomically high.
Despite the fact that these are, you know,
a quote unquote pure endurance athletes,
that the wattage if they can kick out
on a 22nd peak burst on a bike would torch
anything any of you have ever seen.
Like it's insanely high the wattage.
My greatest regret in speaking about this stuff
is that I have yet to come up with a way
to explain to people what wattage feels like.
You see, I think people have an intuitive understanding of what 500 pounds feels like, because
you've been to Home Depot, you picked up the 50 pound bag of salt, and you can sort of
say, wow, deadlifting 500 pounds would sort of be like picking up 10 of these at once.
However, when I try to explain to somebody that when Bradley Wiggins, when Bradley Wiggins
absolutely smashed the one hour record, which is generally regarded as the most pain a
human being can endure in any sport, the one hour record in cycling is that mark.
And he held 440 watts for one hour crunched in a tuck position with his iliac vessels folded
on top of each other. I can't tell you what that's like if you've never peddled. I have to say, look, come and sit on a bike.
I'm going to set the urge to 440 watts.
Let's see how long you can go.
The average person is going to not make it one minute, not even close.
They will not come close to lasting a minute.
The average person is going to be dead at 20 seconds, they will fail. And by the way, they might weigh 180 pounds. And I'm going to say he weighed 138 pounds,
or whatever he weighed. He might have weighed 145. Wiggins was tall. He was probably 6.1. But the point
is he looked like a bean pole. And the force he could generate for 60 minutes is more than you can
generate for 30 seconds.
I don't have a way to explain what that feels like
because shy of doing it,
shy of putting watts to pedals, you can't feel it.
I mean, a thousand, like you put a thousand up there.
That's a big, big number.
I mean, that wouldn't be a crazy number
for cyclists if you did it, you know,
22nd burst or whatever.
Not only that, he's a cyclist is doing that
after riding six hours.
And after riding six hours at an average wattage
of 250 watts, which again, for most people,
they can't hold 250 watts for two minutes.
No way.
So this is a good example of,
this is not suggesting cycling training
is great for power development.
What it's suggesting is when you take
really world caliber athletesaliber athletes,
they're really good at a lot of things.
They're just really, really athletic.
And so what you're comparing your power out
but to that person, you're thinking,
oh my God, that guy's so powerful and he is.
But I promise you, I could put a whole bunch of athletes
on there that can kick 1,200, 1,300.
For sure, way higher than if you had a highly power
trained person.
So when you say like these Crossfiters are miracle,
they're not.
They're just so fit.
They're so strong.
They're unreliable.
I think what makes them special is they're great generalists.
Yeah.
There's nothing that they're the best at.
The gymnast is better at gymnastics.
The weightlifters better at weightlifting.
The powerlifters better at powerlifting.
The strong man is better at strong man. And thelifters better at powerlifting, the strong man is better at strong man,
and the endurance athlete is better at endurance.
There's no question.
Yeah, because we hear the comment too about,
well, they could do this cross-fit competition,
and then they could go do a weightlifting competition the next day.
Like, yeah, but they're not winning medals.
Not a national event.
They're not going to,
occasionally, they might make a world team or something like that,
but that's one person.
What makes them special, and it's worth acknowledging,
is how good they are at so many things.
They're so good.
So, so good.
I don't know if you probably have followed, but like, back in the original days, like,
the stuff that they would come up with to try to get rich, running the lose, it just
didn't matter.
They made up all kinds of stuff and he smashed everything.
You can't come up with enough accolades to describe how talented these people are.
You can't.
It's not bad at all. Demand the women like what they can do is phenomenal.
It just comes back to what you said at the outset, right, which is ultimately specificity
when, and I actually write about this in my book. I was like, look, when I was cycling
and it was all I was doing, I was a really one dimensional athlete. My upper body was
useless. Well, you wanted to be, you know, I wanted it to atrophy away. I was not good at running even though I had the engine running was hard for me.
The impact was not pleasant.
If I was sprinting, I couldn't get my heart rate over 130
because I didn't have the leg pounding strength to cope with it.
No lateral movement, no flexibility, no balance.
Like, there is no other dimension to, other than turning pedals over quickly.
Again, not to take anything away from the best cyclists
in the world.
They're marvels of human physiology,
but it's super, super specific.
And again, I think that's true for every athlete
we're talking about.
Once we get into these strong men and CrossFit athletes,
though, you start to see what in some ways impresses me
a little bit more, which is just broad, remarkable
feats of strength and endurance across a great range.
Think about last example. Just think about an elite marathon time. Let's call it two hours to
make math easy, because it's getting there. Technically it's been broken, right?
Tip Chogi sort of did it once, yeah, unofficial. With some caveats and stuff there.
You break that down for four minutes. For 40? Forty mile. Yeah, maybe even quicker, maybe four thirty four, something like that. It's insane.
We'll call it four and a half. I don't know if hardly any people in my life who could
do that once.
Most people couldn't hold that pace for a quarter mile.
Well, that's what I was going to get at. So you break it down even further. You're talking
sixty five second four hundred meter dash. You will not find many people in this earth
that can run at sixty five second four 400 meter dash one time. You walked that out even further.
That's a 12 second 100 meter dash.
That's like a number that you might be a little more familiar with.
The best marathoners in the world would smash almost everyone you know in a 100 meter
dash.
They're blazingly fast.
Virtually everybody in a 400 in a quarter mile, it's insane.
It's the same thing as the Bradley Wiggins example, or any of the cyclist thing,
it's like, we just don't understand how far we are.
I think the difference is in the running,
I think most people can understand
because they can remember back to high school gym class,
how hard it was to run 66 seconds for a quarter mile.
I tell people all the time,
like go run a four meter dash, like next time,
go time, it's hard.
Like everyone's like, oh yeah, I can be 60,
and it's like, they come in 85 seconds.
You're very far off this number.
So don't conflate world class.
The best we've ever known athletes
to thinking these concepts are then wrong.
Because we're talking about general concepts
with, in this case, not CrossFit.
So going back to this CrossFit athlete,
how are they able to balance the volume?
Because they're now pushing the envelope so much
between strength, power, and endurance
that at some point you're robbing Peter to pay Paul. I mean, you have to. Is the trade-off that
you have to make in that training a function of your incoming athleticism, your genetics,
and maybe your goals? You might say, look, I'm going to index to be better at these events than
that events. Is that the only way you can basically do it? And there is no true way to have a global optimization strategy?
We don't have any science on any of this stuff, and I've never coached crossfitters.
So having said that there are some really, really, really smart, really smart people that are
coaching crossfitters.
So they could probably walk you through, I'm telling you on here, but I don't have any
science to go off of.
In general, though, if you just look at physiology,
specificity, it does matter, right?
So if you were going to optimize somebody for strength,
you could have one of two philosophies.
You could say, look, we're really, really, really strong,
we're good at this stuff, and we recover well from it.
So we're going to stay doing more of these strength type things
because we can actually get more total volume in
because you recover well from it, as an example.
Or you can do the opposite.
You can say, hey, look, we're going to go into a lot of strength because that's the weakest
part we have, and we're going to try to bring our weakness up.
So it's kind of a coaching philosophy of maximizing strength or trying to minimize your
biggest limitation.
In terms of like actual total volume to get per week and stuff, again, I don't have any
actual numbers on that.
Everyone does this quite differently. What I can say is it's so beautiful across it in
the sense that you need to have a ton of baseline aerobic capacity. You need to have some
peak power. You need to have some strength and you need to be highly anaerobic and you
need to have real high recovery from anaerobic efforts. You have to find some sort of combination, which is like
to me, one of the most, if not the most fascinating part of the whole thing is like, what do you do?
And nobody has an answer. It's just strategy. We're going to try to go here. The other strategy
they have is just, we're just going to hammer everyone. See who's left and you're going to be
ready to go there. So what do we know about heart rate recovery as a model of fitness? I am guessing
within the CrossFit athlete, that's a very important part of it, as you
point out, the anaerobic recovery is essential.
It's a strong metric.
It is very good.
In fact, you'll see this, there's a number of different places around the country where
you can just go and get a view to the access done, like you'd go in and pay $100 or something,
which is great.
A lot of the time, so actually, if they're good, they'll look at one, two, and three minute heart rate recovery as well. Because you didn't gain a lot of insight
from there. Do you have off the top of your head what the metrics are that we care about for 30,
60, 120 second recovery? 80% in two minutes. You mean within 20% of baseline?
Say you're at 200. There's no reason you should be above 160, two minutes in. So two minutes
recovery, you should be well below 160 beats if your max was 200
So that would be 80% of your max you should be well below that by the two in a mark
Oh, that's much slower than I would have thought I would have expected within two minutes
You'd need that would be like minimum minimum. Okay. What's considered excellent 60 so in the functional case
You're gonna be down to in this thing 120 beats, which is like almost is gonna to feel like you're resting after that. You're going to feel like you're barely even ventilating,
but that would be a solid number to be at. If you're above 80 though, it's like, soundly alarm.
This is a real big problem. And then you can walk yourself down.
Do we care what an athlete's maximum heart rate is? In particular, or do we care much more about,
for example, heart rate recovery and what they can do at their max heart rate?
In other words, I'll give you an example, right? So VO2 max surprisingly is not that correlated with speed.
It's VVO2 max that is, right? So velocity at VO2 max matters much more in running than VO2 max.
Encycling turns out VO2 max not nearly as important as PVO2 max, power at VO2 max. Encycling turns out VO2 max not nearly as important as PVO2 max, power
at VO2 max. But at least when I was training, we were not looking at heart rate recovery,
meaning I wasn't, and my coach wasn't. But I wonder if that's a metric that we should
have been paying more attention to in addition to kind of PVO2 max and FTP and all those
other metrics. If you look at VO2 max specifically,
I can't come on a cycling.
I don't know all those data that literature will.
I do know running literature.
You're gonna have three main components
that are gonna predict endurance running
and VO2 max is only one of them.
Running economy is very, very important as the other one.
So they're all three in Lactic Threshold,
of course, is like the sort of trying goal of things.
Any one of them on its face is not gonna get you anywhere
and all three of them are still not gonna get you everywhere.
So movement economy on a bike, it's probably similar.
Probably more of your power ratio, like Sertzik and I.
On a bike, it's actually last, believe it or not,
on a bike, it's FTP to weight.
Which is effectively efficiency.
Like how far can you travel on a bike per push?
That's what makes cycling to me,
such a remarkable feat of engineering.
It's basically just machines.
It's take your
functional threshold power, divide by how many kilograms you are, that's a number. If you line up
everybody at the beginning of the Tour de France and rank them in that order, that is the order
they will finish barring in accident, or a strategic blunder. And you can make strategic blunders.
Yeah, because efficiency on a bike is super high, where efficiency and human movement is like 20%
or something, like super, super low, whatever that number is.
When you actually start to pay attention to what metrics do you pay attention to, max
heart rate, are you going to find that as a predictor of any kind of performance?
No, with the exception of whether people stop way prior to hitting a max heart rate.
So that would be like if you're going to do a video to max test, one of the five metrics
you look for to identify to make sure it was an actual max test is whether or not they
get close to their predicted hurry max. And so you will see this occasionally people stop at 150,
155 heart rate, 160 maybe or something and they're not. When they should have been 175. Correct.
That's also like can just happen normally. That's how a lot of high level athletes max
harry 172 and 175 and you're like very fit fighters. The championship fighters kind of thing five
five minutes rounds are going to fight the OC and they like, it's just sort of where you are.
But they can also cruise 168 for a whole round.
Like one a minute rest and do that for a fight.
Really like holy crap, okay.
So their ability to hang on at 95% in this case,
it's like 98% and they can just hang there for minutes
where most people get to 98% and you have seconds of life
before you're asking for something.
So it is a little bit of a crew. I've also had people myself included. I'm still well over 200
as a max heart rate. Wow. My RR too, like it's nothing. If I do a video to max test and I am
like lower than 1.3, I know it was not a max test. Technically, you're not supposed to get over 1.1.
1.35, 1.38. Those are not crazy numbers for me to hit. I just handle that stuff super well.
What's your resting RER?
Is it still close to 0.7, 0.75?
75, typically.
And those numbers are like kind of a workplace.
My CO2 tolerance is also very, very high.
I can handle a large buildup of waste.
My VO2 max overall does not particularly high.
Relative to these things.
55, 58, depending probably lower than that
right now, but I've never crossed 60. It's kind of relevant, but it's also not. So the problem is
is you're very aware I'm sure when heart rate gets too high, you start limiting time to fill.
Yeah, your preload is low and your stroke volume goes down. Super low. So stroke volume gets super low.
So it's not always the best thing to be super high. And then there's some other factors here in terms of like accuracy of measure
and some other things to be attention to.
But in general, it's not a proxy.
I don't know if we talked about the study I did in Sweden
with the cross-country skiers in their 80s and 90s.
But I can't remember, I think our average max
heart rate was like 150, 148.
These were 80 and 90-year-olds, and they didn't care at all.
They were at 150 and they were like
It's amazing like no lifelong athletes though. These guys never got out. Oh, yeah, right. These guys were
These are from their team champions never stopped totally world champions in the 1940s and 50s And are still competing every year across country skiing so never stopped just savages
These guys have VO2 maxes in the mid 30s probably still yep, perfect 92 year old. I think his VO2 max is in the mid 30s, probably still. Yep, perfect. In the same. 92 year old, I think his VO2 max was 38.
I remember correctly, something like that.
Several of them over 40, 86, 88 plus year olds, crushing.
We had such a long conversation that the first time I can't remember if I told the story
to say apologies if I did, but I'm going to tell it again, but one of them in particular.
So we were over in Stockholm doing this and these guys, I don't speak Swedish and they
didn't speak English.
And we're in a hospital, so there's cardiologists there, And we're trying to, like, as you do a video to max
such, like you're yelling and encouraging to go,
go, go, go, right, whatever.
And one of them got done, we were cycling.
He got off and he sat next to the hospital a bit.
He took like three breaths.
He's like, he said something, my ass,
well, they said they like,
he said he didn't understand the instructions.
He wants to try again.
And he got up and he started getting back on the bike.
And we're like, whoa, like, and I'm talking 15 seconds.
Whatever takes you to take three breaths.
He's just like, go back on the bike again,
we're gonna go, I was like, this guy,
and they're like, no, no, no, no, no, no, no.
I was like, let's go to the wall, let's see what he has.
I love it.
Cardiol just said no.
Again, I think the CrossFit athlete in some ways
is of all of the athletes we're talking about here,
the one that is most representative
of maybe what our long-term realistic goal is, not necessarily at that
extreme, because obviously I think when people think CrossFit, they think of stuff that they're
never going to do. But in terms of being a generalist, I think that's the closest one we're going to see.
So is there anything that is off limits? In other words, if you exclude pre-existing injury, so,
you know, we're not talking about somebody with a laboral injury that can't be doing power cleans and snatches, how much of your time and
energy is going to go into max rep powerlifting movements, relatively heavy weightlifting movements,
given that you need to do so much other stuff and build that base of endurance.
Let's just assume, for the purpose of this discussion, you're optimizing around being the most well-rounded, not being a spike in one particular
domain over another. Okay, 70, 2010. This is the number 70, 2010. I got this from my friend Kenny Kane,
who ran CrossFit LA. So I think it was like the eighth or ninth CrossFit, or one of the original
ones, still coaching to this day. So been long at it. And the way that ninth CrossFit, one of the original ones, still coaching to this day, so we've been longer than that.
And the way that he programs it, he's in Santa Monica, so he doesn't have a lot of CrossFit
competitors.
The avatar you explain is pretty much his client.
It's people who learn 30 to 50 and all those things.
His model works perfectly here.
So what he says is 70% of the time, you're in the gym.
You're there for practice.
And what I want to point out here is,
if that doesn't mean we're like practicing barbell only
and things like that, you're gonna go through a full workout,
you're gonna sweat, you're gonna get tired.
But the core of what we're after here is practicing.
So we're getting better at, say, technical proficiency
with a little bit of fatigue.
We're getting better at hip-hinge.
We're getting better at breath mechanics.
We're getting better at pressing overhead. We're gonna use fatigue and load to get better at hip-hinging. We're getting better at breath mechanics. We're getting better at pressing overhead.
We're going to use fatigue and load
to get better at something.
70% of the time we're practicing.
20% of the time we're going to compete,
which is you're going to try to get your best score
on that workout, right?
So we're going to put it up there, you know,
10 minutes, how many rounds you can get to, whatever.
And you're going to try to get the best number
you can in that workout, which is very different.
And I noticed the shift here.
Practice is 100% emphasis on quality.
Who cares about the score?
20% of the time, though, it's the opposite.
It doesn't mean we're going to let technique go.
It's just the mind frame is different.
We're out here.
We're trying to conserve our efficiency.
So if we're doing, say, box jumps for reps, we're not jumping up as high as we can every
time.
We're actually kind of doing the minimum amount we can to get up, get back down, we're being careful and calm, and we're trying to get the highest score on this workout in the camp.
10% of the time, we go to death, basically, which is like, we're going balls to the wall.
We're not trying to hold back. We're not trying to be strategic. We're trying to get to death stores as fast as we can, and just live in the sock, basically. So if you do that in your brain,
let's say the average person per month
is gonna work out 12 times.
So that means, all right, three times a week,
I'm gonna go to the gym for a week's S12.
All right, so then like maybe eight of those workouts,
which is twice a week, I'm gonna be practicing.
Again, you're gonna get a good sweat,
you're gonna get stronger, you're gonna build some muscle,
but the intention there.
Then maybe three of the workouts left are going to be those competition ones.
Then one of them per month, we go absolutely nuts.
Again, we're trying to not hold back.
We're going to go after it and we're going to lay on the ground for an hour afterwards
because it was just sort of awful.
I think that's a very, very good way to think about how you want to train for a sport
like CrossFit because the movements are what they are.
You're going to get better in a lot of ways,
you're gonna stay safe,
you're gonna get a little bit of that like,
oh shit, this is gonna be crazy today.
Like a better not drink tonight,
go to bed early, because tomorrow is that,
and then there's enough of the 20% or is where it's like,
it's really, really hard this week.
One day a week is super, super hard.
Because the other big problem we see with the people
that train like this, that also have real jobs, is how much time they spend in sympathetic drive.
And they end up just torching themselves because it's too much time intensity too often, and they don't understand when to like dial it back.
So if you kind of have this model, it's sort of like two days a week, you're working out and blood pumping, you're getting feeling good, it's recovery, you're going to feel great one day day a week though, you're gonna push it harder. And then one of those four weeks,
that one hard day is really, really, really hard.
And that's enough for most people
that have other life stressors.
You'll be able to recover from that stuff,
but also then feel, you're not just sort of like,
not getting anything out of your training.
So 70, 2010, I think is the perfect model for this.
So I'm glad you brought that point up.
It's so important when I think about the difference between my life today and my life
when I was 18.
You know, there are a lot of things that were better when I was 18, just physiologically
or so much stronger and fitter and all the rest of it.
But also a big part of it is there was no other sympathetic drive to your point.
Anyone who's got a teenager knows, they're like the singularly most selfish creatures
on the face of the earth, they're incapable of caring about anything that is not themselves.
So everything in my life revolved around my workouts.
Tell you a funny story.
One day when I was coming home from school
to do the third of my four workouts for the day
because every day had four workouts in it,
I forgot my key and I couldn't get in the house.
So I actually broke into the house,
like I actually smashed a window to break into my house
to make sure I could do the workout.
And that didn't strike me as a weird thing to do.
Putting, I can't remember if I used my fist or a brick, but I literally just broke the window,
got into the house, didn't bother to clean it up, and was in the basement, hammering the weights
when my mom came home and thought there was like a breaking. Didn't occur to me as a random thing.
So again, there's no weather stress in my life. There's nothing else that matters other
than training. But then you're 50 and all of a sudden life is stressful. Is there a way
to quantify and help people think about that as it factors into the training load equation
if you want to think about that way?
Scientifically, there's a name for it called Alistatic Load or Alistasis.
That's what it means scientifically
of all stressors combined.
Lots of ways you can do this,
we have our own algorithm that I use
that we actually factor in everything.
We actually break it up into what we call visible
and hidden stressors.
So visible stressors are visible
because you see them or feel them.
You know if you didn't sleep well last night.
You know if you're thirsty right now.
You ate that food that visibly was probably
not the best choice. Alcohol cigarettes
like sort of call these things.
Hidden stressors are things that you won't necessarily feel
in a moment.
So maybe your carbohydrate to protein ratios off
or your way too high in carbs or too low in carbs or something like that.
Maybe you've got some medical condition, some pathogens,
some micronutrient,
deficiency, excessive inflammation,
like something else where you just like,
my recovery sucks, but I'm doing all the right things.
So we put all that stuff together,
we measure all of it and then we actually
can kind of score them.
And then we base our programming based on those scores.
That's how we do it.
How would one do it if they didn't have blood work
and saliva and urinary and kind of the whole thing
that we have.
You can't just go from the visible side and just try to put a score.
If you did something as simple as how was your sleep, on a 10, how was your psychological
and mental stress, how I'll age each and then like overall recovery feel like those
four alone will get you like somewhat close because think about it this way.
Adaptation in the body happens because of stress.
But because we just talk that stress bucket can be overfilled, what you want to do is dump
as much stress in from the type of stress you want and have as much of the other stress
you don't want out.
So if you're already pre-filled with other stuff and you put a little bit of training
stress on there, you're already overfilling here.
If I can dump that other stuff out of the equation, I can dump more and more and more training
in before we start overfilling. If I can dump that other stuff out of the equation, I can dump more and more and more training in
before we start over filling.
So that's why it's very, very important to keep that
allesthetic load.
I'm not down.
You don't want it low, because remember,
you have to have stress at the cause of notation.
You just want to fill with the right stresses
that go in the right direction, specificity, right?
The more specific the stress can get,
the more specific the outcome can get.
So those are the big rocks I'm sure you've talked about
a trillion times. But that's why that stuff is very, very important, paying attention to the
total amount of static load. I'm going to skip the track athlete at this point. So this is...
We can do it in two minutes if you want. Right, let's do it. And should we just limit it to
not the field side, but just the track side. So we're talking sprinters. So these guys are insanely
strong. If you put them on a force plate treadmill, I've heard you saying both is literally hitting at four times his body weight on a force
plate treadmill. I don't know if that's true, but I would believe it. So what are we saying
here? This is highly technical, meaning technique really, really matters, efficiency really,
really matters. And then it's forced to wait. I assume.
Close. There's some more factors at play here, because force is not the real driver here.
Speed is, you have absolute acceleration,
and then you have peak velocity.
When you say it comes out the gates, that's acceleration.
He's not particularly strong relative
to his other folks acceleration,
probably because his force production
is not like exceptionally high relative to the other ones.
However, once he gets vertical,
his peak velocity is so outrageous and his ability to maintain other ones. However, once he gets vertical, his peak velocity is so outrageous.
And his ability to maintain peak velocity, in fact, if you go, look, that's the thing
that really separated him. He maintained that peak velocity so much longer than anyone
else did. So it looked like he was passing everybody. He wasn't that they were just slowing
down.
Field is slowing down. So you have peak velocity and you have acceleration. For other field
sports, you have change of direction and agility.
The difference there being your determination versus reacting to stimulus and change of direction.
Okay, so that's what we're at.
In terms of are they strong to you?
You have legendary stories of 100 meter dash,
spent for squatting 600 pounds.
It's the same thing we talked about earlier, fallacy of like when you're an elite athlete,
you're probably good at a lot of things, but doesn't mean you're optimized for it.
So they need to be strong because they have to overcome force, 100 meter dash, 200 meter
dash, boom acceleration piece, but then they have to have true elite speed, which is a function
of how fast you can turn your feet over and running as well as your straight line.
And so that is like a technical component to it as well. But training for peak speed is just those two components. So you use a little bit of resistance,
fairly lighter than power or the low end of the power spectrum, 30% or less, to train the
acceleration part. And then you move as fast as you can. You either use normal or over speed training
to train peak velocity, which should make intuitive sense now
to be sort of walk that conversation.
So you train those two aspects of speed,
and depending on where they end up in the velocity,
is they made a little more force,
or they may need a little more actual
of the peak velocity stuff.
And then you use that on your force velocity profile
to figure out where that athlete needs to train.
And then just to finish quickly,
if you go back to the entire matrix,
speed training
and power training are almost identical.
You can do them at a very high frequency.
You want to do complex movements.
You don't want to do typically isolation single joint movements.
You want to do things you can move as fast as you can.
You can do them very frequently.
If you're a very late sprinter, you've got to be careful of your hamstring and stuff like
that.
But for the most part, physiologically, it's low fatigue, it's low total volume, it's high quality,
and you just now are going lighter so that you can move faster.
That's really the only difference.
Just to be clear, are you saying that the workout of actual running, like for example using an assisted, like a slight tug run,
that type of workout could be done frequently.
Yeah, there's no fatigue, really.
There's no joint beat up, there's no systemic fatigue.
So just to contrast this to like, when is the sanction we may have crossed for that's very important.
The reason why we talked about only doing high intensity stuff so often in CrossFit,
it's because it's the first one we've talked about, the only one really of this group,
maybe some strong man, but it's the one
that has the most systemic fatigue associated with it.
The rest of them are pretty much localized.
Your back might get tired
because you had a heavy load on your back,
for a back squat,
and your hamstrings might be tired
because you sprinted maximally right now.
But you're not gonna see your HRV get tanked.
You're not gonna see a global total fatigue, like you would let in across the
scenario because it is whole muscle.
It is cartilage-ascaroid driven.
There's an endocrine response that's massive and that doesn't happen.
So because of that you have systemic fatigue.
So that distinction is why I made that distinction earlier.
And you also at the, I think it was on the power lift or weight lift, we talked about sort
of the neurologic component of this.
Can you say a bit more about that? So when we get into power lifting a little bit,
and now really into weight lifting,
and certainly in as we've gone down the spectrum here
into true speed stuff,
there is such a high component to neural activation
to make sure that we're not only optimizing
all the motor units we need,
but in the case of speed,
you have to do them in the right sequence.
And so movement mechanics and being smooth, and of speed, you have to do them in the right sequence. And so movement
mechanics and being smooth and the rhythm that you have to have to move actually fast as a human
is very, very challenging. And so that rhythm is very important. So this is called synchronization.
You have to be firing the right muscles in the right group in the right order throughout your
gate, if it's, say, running. And that's not necessarily the case in powerlifting, or even so much a little bit in weightlifting,
but not much in powerlifting because everything's on
and maximum, and you're just controlling everything.
But like rhythm, the common order you'll hear in
like sprinters are running, like you got to be in the rhythm.
And you might get faster without actually improving
your velocity ability by just getting in better rhythm.
And what they're meaning by that is learning what to fire,
what to relax, and having that fire relax, fire relax,
so a joint can move and then be ready to strike again
and be ready to strike again.
But is this autonomic or conscious?
It can be both.
The idea would be to make this as subconscious as possible.
So you're just in the moment relaxed and moving
and everything is understanding when it contract
and when they're relaxed.
And initially though when you learn it,
it's going to be very conscious.
What is the most taxing workout that the sprinter is doing during
the week? What is the workout from which they need a recovery? Probably their true peak speed stuff.
Really going true peak speed. There's a little bit of risk there, but the fatigue and being able
to come back and reproduce peak speed, because here's the distinction. If you did a crossfit workout,
and you were able to maintain 95% of your peak speed from today
to tomorrow to the next day.
So let's say you did a workout today and you had a little bit of residual fatigue.
Tomorrow when you came back, if you're 5% reduced, you could still probably do your workout
because you could use other components.
You could use your strength, you could use recovery, you could use all kinds of things.
If you're trying to train maximum speed and you're 5% slower tomorrow, then we're not trying maximum speed anymore. And so it's just a level
of recovery that has to be higher to be able to achieve what we're trying to go after
here, which is hitting a new actual peak velocity. And so it's not the fact that you're like
super sore. Generally, you're going to feel fine, maybe a little sore, but your number
is your 3% lower. You're like, damn, not recovered enough.
We're almost everywhere this is where you'd be like, great, that's totally fine.
Go play.
Let's kind of now tie this all together for a totally different type of athlete that
most people aren't thinking about, which is the centenary and athlete.
And I'm not assuming that we're starting from the standpoint of having been world class
Olympic cross-country skiers in our 20s who never stop.
I'm talking about somebody who's in their 40s
who, I don't know, kind of has the epiphany
that says, wait a minute, like, it's cool to be a power lifter,
it's cool to be a weight lifter,
it's cool to be a cross-fitter, a strong man,
an elite runner, cyclist, swimmer, whatever,
but I'm gonna pick a different sport.
I'm gonna pick a sport where the optimization is around my ability to be as physically
robust as possible in the last decade of my life, which means I want to build a bunch of
things that most people can't even fathom when they're 80 or 90 years old.
That means like I can run up an escalator if it's broken, carrying my luggage.
I can put the 25 pound bag in the overhead compartment
of the airplane.
I can pick a grandchild up out of a crib.
I can play on the floor and stand up on my own.
No issues.
I can go for a hike on rocky terrain
and I'm not gonna slip and fall.
You know, again, things that you would do blindfolded today,
but the number of people
in the last decade of their life that can do this, you can count on a few hands. So I'm going
to argue that to train for that, you have to make trade-offs. One of the biggest trade-offs you
have to make is optimizing against getting injured because the compounding effective training is so strong that it's rivaled only
by the compounding effect of not training.
Correct.
You know exactly what I'm saying, but for the listener, you will lose it way faster than
you will gain it.
And therefore, you could argue rule number one of what I'm proposing is you can't ever
stop training to have an injury that sidelines you for three months
is an unacceptable risk.
Even if the concessions you make for that
cost you some peak performance.
Okay, so armed with all of those caveats,
what would we beg, borrow, and steal
from each of these phenotypes into our centenarian de-Cathlon?
We're gonna work backwards, which is physiology first.
So you have three things you need to train.
And if you train those three things,
you can steal from any of those areas
you'd like to get those three things done.
And you can mix and match, and I would argue you should.
So thing one is you have to have high quality
functioning muscle tissue.
Number two, nervous system.
And by that in large part, when we typically think about the nervous system for exercise,
we often think peripheral.
I'm even talking central vis-a-vis the brain.
And then four, cardio pulmonary, sorry, three.
So we need to make sure that we've got muscle.
We need to make sure that our motor control is very, very astute. And then we need to make sure that our gun muscle, we need to make sure that our motor control is very,
very astute, and then we need to make sure that our cardio pulmonary system is high functioning.
You do all three of those things, you're going to be able to do all those activities you talked
about a second ago. The distinction of the brain is very, very important because if you were to go
to a sport like powerlifting, the downside is while there's a lot of neural activation required for peak force,
the lack of variation and the lack of range of motion is a problem. One of the things that
is become very clear, preserving brain health, I'm not sure actually there's a recent paper
by my friend, do you know Tommy Wood? I do know Tommy Wood very well and I've been meaning
to have Tommy on the podcast, I need to get him on the podcast. Oh, to Tommy would smash. Did you see his paper on late onset dimension?
Yeah, yeah, super clear.
In my opinion, that one of the key components to maintaining brain function
throughout life is proprioceptive innovation.
And so you need to be moving in space and learning your site.
So if you think about this from the exercise perspective, if the octane,
the 100 year old, 90 year old, you need to have some physical activity that is uncontrolled.
You don't want to be moving up and down, same foot positions all the time.
This could be an outdoor hike.
We're engaging with the environment, plus the steps are non-uniform, tyrannous, lippy,
whatever.
It could be a sport, it could be surfing, it could be badminton, it could be anything else,
but you need one physical activity in your plan that requires you to react to the world. Strong men probably checks that box
a little bit. Probably a lot, maybe not a maximum, but a lot. Weightlifting checks that box pretty
well. Olympic weightlifting. Running, sprinting, checks the box decently, right? You're moving,
especially if you can kind of walk. And so you can kind of walk through the rest of them cycling,
probably wouldn't check that list very well, right?
So we want to think about that's the first thing.
That's what's needed.
The second thing that's needed
is high-force production.
So you preserve your nerves by asking them
to do a lot of different things, Tommy's paper,
and by asking all the motor units to work.
So something throughout your week
has to be high-force production.
And by high-force production, I'm going to say
greater than 80% of your max.
That could be power lifting, could be weight lifting, could be strong man, could be crossfit,
no problem, could be any of those things, could be different plyometrics and stuff like
that.
All right, nervous system is checked, those two components.
Cardiovascular system, I think the cardiovascular system needs to be able to do two primary things,
I'll split it into three.
It needs to be able to sustain consistent work output
over a minimum of 30 minutes with no interval,
like no breakdown, call this zone, whatever, I don't care.
But this is no break whatsoever.
We left him does not check that,
power left him does not check that, strong man,
maybe, but you're probably going to be taking some breaks.
CrossFit might be able to get away with it.
You might be able to do a 25 minute. You might be able to 25 minute workout
with almost no dip,
but you may actually need to integrate
more classic steady-stake stuff here.
This might be an air bike.
This might be a sled push.
This might be a jog or swim.
It's like something like that.
So that's one component card
that's the system has.
The other one is has to be able to get the max heart rate.
You gotta get all the way up there.
So CrossFit, absolutely strong man, absolutely power lifting, kind of, if you're going heavy enough,
you'll get up there. You can get blood pressures of 450 over 350 during a winter max
day lift. You can get complete inclusion basically, but probably not the place I'm starting for my
max heart rate training. That's not really an option. And how many times a week do we think a
person needs to experience their max heart rate?
For this athlete, again, not talking about a real athlete, but even just once a week
of hitting that max heart rate.
It takes the systemic fatigue out of it.
I would love to.
To be really, really good.
If you can really handle it, if the alisatic loads low, three would be fine, but I would
say minimum one, most people should for two.
That's great.
I would say the same thing for the steady state piece. Once good, two might be better. It depends on what you're doing.
Like if you're also doing a lot of like long, just walking, you might head your bets there a little
bit. And then the third one, maybe in this category, is recovery from high intensity stuff. So,
not only just be able to get your heart rate up high once, being able to come back down,
regulate yourself, come back up, regulate yourself back down. And that can be certainly
known with CrossFit, because certainly known as wrong man, regulate yourself back down. And that could be certainly not the CrossFit, because it certainly not the strongman,
maybe down to a few other things, but that's kind of where we're at there.
So, if we were to kind of go back to beginning one day a week playing as some uncontrolled,
one day a week has got to be really high force.
One day a week has got to be max heart rate, one day a week has got to be sustained heart
rate.
Those could all also be combined.
There's no reason why you can't go in
to 10 minutes of pure strength training,
check that box, and then go place and pickle ball.
Check that box.
You could do max strength stuff for 10 minutes,
and then go do a crossfit of 20 minute amaranth.
So we doesn't have to be like 100 nights,
we do this whole thing in 40 minutes, easy.
So we do those two things. We've checked
off cardiovascular health. We've checked off neurological health. Then the third one is muscle
health. And the muscle needs to be able to do a handful of things. It needs to be sufficiently
strong, which we sort of already talked about. It needs to be a sufficient size. Okay, now we don't
need to be excessively large, but there's some minimum requirement we have to have as we age.
Do you think about that from the standpoint of like ALMI where you really want to see somebody above.
We hold patients to a very high standard. We want our patients above the 75th percentile for ALMI.
You see a big step up in mortality benefit above that.
How do you quantify that for folks?
So you can look at that.
Depends on how much data you can get in them.
FFMI is also like a crudely okay.
If you get into the above average or higher, I'm good.
Is it literally something as crude as FFMI and ALMI
as an anthropometric measurement of size?
I think it's totally fine.
What you're going to see generally is a tighter line
between strengths than you will see size.
As you move up, we probably are out of time,
but there's a whole discussion. The whole idea that like too much muscle too much muscle mass detrimental to health and age is a giant misnomer
There are nine other topics that I want to discuss that we won't but we'll come back and do them in round three
And that's one of them because you you've just hit two of the nine remaining topics one of them is
exploring the myth of
One of them is exploring the myth of strength is paradoxically harmful as you age. Too much strength, right?
Strength, athletes, struggle is age.
We'll go through the debunk of that.
Yeah, that's super easy to debunk too.
And then also talk about the uncoupling of strength and size, because both of them are so
highly correlated with longevity as is cardiovascular fitness measured by VO2 max.
But I love the idea of uncoupling them a little bit because my reading of the literature
is that strength trumps size, you know, but anyway, you can sort of get into that.
So strong and enough size.
And I also think one of the arguments that says size still does matter goes back to
the non functional or non structural component of muscle, which is the metabolic
component. So it can never lose sight of the fact that this is our greatest glucose reservoir,
and the metabolic benefits of having a huge glucose sink are enormous.
You want to keep your inflammation, though.
There you go.
That's a key component to it.
So the last part around that is your skeleton of muscle needs to have muscular endurance.
So it needs to be able to do something for 20 repetitions and a row or something.
And this is very important for, again, walking up 15 steps, 20 steps.
This is not going to be cardiovascularly limited.
It's going to be limited by the local muscle endurance.
It's going to be limited by your strength, actually.
It's like another totally missed thing.
When people think like, wow, I walked up on fly to Stairs and I was out of breath.
I'm so out of shape.
No, you're weak.
Because what happened is every step was 85% of your 1-Ret max.
And so that became very, very, you just did, you know, 12 reps at 85%.
If you were stronger and that was 50%, you wouldn't be out of breath.
That's a really great distinction. Yeah, I'm really glad you're making that point.
This gets strong. And all of a sudden, while you're that task was not as hard.
Even with the steps, what makes it so elegant is it's actually strength to weight ratio.
So you might even say, well, but I am kind of strong and it's like,
not for your weight, you're not. And the gravity now makes it your strength to weight ratio. So you might even say, well, but I am kind of strong and it's like, not for your weight, you're not.
And the gravity now makes it,
your strength to weight ratio is not high enough.
Correct.
That's where your fatigue is coming from.
Which is a precursor to like the U curve J shape thing
of too much muscle mass getting large.
As you age, just higher mortality.
It's like, you're looking at bigger people,
which you're really looking at, but anyway.
What are some of the do-nots?
So we've talked about what they need to do.
But if you go back to this caveat that I've placed on you,
which is I'm going to make you ZAR for the day on training here,
but I'm going to say, I don't want to see people getting injured.
I want to make sure that there's no interruption of training.
I'm going to argue that the older we get,
anytime we have interruptions in training,
the cost of regain is so high. So how do you factor that into a strategy around training for this person? Exercise and just injuries happen in a couple of ways. It's very, very rare that it's
muscle. That's the problem. The only problem that you have with the cardiopulmonary system or
cardiovascular system is systemic fatigue.
That's not really its fault, right? Systemic fatigue.
So, if you're not overdoing it globally, and this would be your run down,
this is maybe you're getting sick really often,
any number of hormone cascades or adoac cortisol to testosterone, all off,
like things like that, mood, can't sleep, appetite,
like those are some of the markers we look for of global fatigue.
So if that's not what we're talking about here, you're talking about, I got hurt through
my back out when knee hurts.
Yeah, neck is this, knee is that, back is that.
What you're talking about is joint.
So the only reason joints really get hurt is repetition over bad movement patterns.
So as long as you're moving well in those joints, or not moving well, depending on the
joint, and not moving at all
rather, then you can really do unlimited amounts of volume theoretically until the point you hit
systemic fatigue because it's not going to be muscle that's going to be the problem. You'll have some
muscles, strains and stuff like that, but this is not putting off for three months that you tear
something off the bone or whatever, connective tissue. So it's connective tissue or it's going to
be joint. So how do we keep those things in place?
We need to move properly.
The first step I would do,
if we really had this like 40 year timeframe,
is I would invest heavily, heavily
in understanding proper movement patterns,
and then I would load them very specifically.
So step number one, you need to make sure
you can do the movement pattern perfectly with assistance.
Let's do a squat and put your hands under the rail and squat all up and down.
So you hold onto the band grab up.
Okay, great.
You can do it with assistance.
Awesome.
How about body weight only?
Great.
Step two, you did it with body weight only.
Step three, now we can add a little bit of eccentric load.
So I want you to just lower the thing down, down to its full range of motion.
We're all in good positions. You're under control. We're right here. If you can do things eccentricly, I don't care what
the load is. Give me your body weight. Still. You can control the descent of the pushup.
You're holding proper position shoulder neck, low back, all the spine, which is generally the
problem, right? That's all in the right position. Great. Fall on the floor. Start back to the beginning. Great. We're under control. We're good there.
At that point, we can now look to get into the unilateral. Okay, great. So you did it great when
you had two limbs. Can you do it great when you just your left side? Yeah. Can you do it great with
your right side? Ooh, no. Okay. Now we're going to start predicting, giving enough time and enough
volume and repetition. We're going to start seeing a weakness, which means we're going to have a compensation movement, which means we may
start getting all of a sudden low backness hurting now.
Or why is your left knee hurting?
Why is your right ankle hurting?
Something was probably moving slightly wrong in one position.
So we're going to do it, a unilateral evaluation here, making sure we're fine now.
Once you check that, both.
We haven't even got the loaded yet.
We're just saying,
can you do it? Can you do the movement? Once you pass all that, now we introduce load.
Okay, great. We also know, once you can do all those things and you pass it with load, now
we ask speed in the equation. So can you do these things in the exact same positions when I ask you
to go as fast as possible? Second, the last step is then you add fatigue. Now you notice,
what's the vast majority of time people
started to work out.
The vast majority of the way that they progress is,
they add volume.
I'm gonna go for a mile, I have a random forever,
I'm just gonna start working out,
I'm gonna run for a mile, tomorrow run mile and a half.
They just start adding volume.
We are adding volume on top of dysfunctional movement.
What do you expect is gonna happen six weeks, six, whatever.
If you can do all those
things, then I know you move perfectly well, eccentrically and concentrically. You can do it in
bilateral or unilateral position. You can do it with load when I ask you to go fast and when you
get tired, rip and roar now. Like we can do whatever. We can do absolutely anything. And we're going to
do that through a variety of movement positions. So overhead pressing, overhead pulling,
horizontal pressing and pulling, lower body hinging, lower body pressing, rotational unilateral
support, diagonal, all over those things. And once we're clear there, now we can start
saying, okay, we can put any of these exposures on you that you want. You want to go after
cardiovascular system first? Probably a good strategy. In fact, there's actually data suggesting we have a count recently showing
that six weeks of pure study, state, endurance training, I think there's a cycling, like 45
minute cycling. Prior to hypertrophy training resulted in more muscle growth at the end of the
hypertrophy training than the group that did do it. So being in good aerobic fitness
is quite powerful and important,
even if you're trying to get muscle mass.
So you could go after those other goals later,
but the big thing in-
And by the way, in that study, was it because
the cycling trained group had a higher work capacity
when they were doing the hypertrophy training?
I think actually, let me get back to you,
but don't hold me, I got to do this, but I think the total workload accomplished in the actual hypertrophy training. I think actually, let me get back to you, but don't hold me, I got to do this.
But I think the total workload accomplished
in the actual hypertrophy training study was the same.
They controlled for that.
So they almost paramatched them to.
I'm pretty sure which was the sneaky part.
Wow, that's super interesting.
Don't hold me to that one exactly though.
That may be wrong.
We'll take that one offline.
Because one of the injuries that I think a lot about,
and I see it happen,
I don't know if this is the classic middle aged guy injury,
but it's that torna killings.
And it's usually, I don't wanna stereotype it
because I'm sure there's someone in whom
it hasn't happened this way,
that it always seems to be the athlete
who's been a little inactive for a while
and then he goes right back to that indoor soccer match
and like boom, you can hear it across the gym.
It's so loud. You're going to be asking a connective tissue, in this case, boom, you can hear it across the gym. It's so loud.
You're going to be asking a connective tissue, in this case,
that Kiely's standing, from never contracting
more than 50% of its max for years,
to all the sudden going to a maximal contraction
on a hyperloaded eccentric stop and change.
How can it happen?
You're going to tear something somewhere.
Probably won't be in an ACL, because Achilles
is going to go first.
You know, I was often see in pro sports Achilles go
because it's gonna handle a lot of ACLs gonna go first.
So in your case, it's the opposite.
That is Tissue tolerance.
It's very, very easy to avoid
with some small amount of tissue tolerance,
which is basically a fancy way of saying,
like just expose the tissue to that demand slowly
and increase that demand over time
and it's gonna to be just fine,
unless you're going to success it.
One of the things that I just find so great for this,
especially as I'm getting older is always warming up
with some sort of jumping.
And it's just multi-planar.
It's really simple is back and forth, back and forth,
back and forth side to side, side to side, side to side.
And then it's one leg out, one like doing the clock.
I don't know if you know that drill, right?
You've got one leg going out to one o'clock, two o'clock,
three o'clock, four o'clock, five o'clock,
and by five and six o'clock,
you're actually having to spin yourself backwards.
And you're always coming back to the center of the clock,
if that makes sense.
And again, these aren't huge jumps,
but the goal is just to introduce lower leg variability
and tension within the tendons
and the connective tissue
with the lower leg at unusual angles.
This is actually why I am a more of a proponent now
of running than I used to be for health.
I would initially was apprehensive against it
because if you look at all forms of exercise,
nothing even compares with injury rate than running.
Running is my far the highest,
nothing will cause more injuries than running for the average exercise, for a lot of reasons, right? So I'm like, it's
stupid. I actually have changed my thought on that now for this exact reason. Just a small
amount of running is enough to keep tissue tolerance through most of the lower half to
be able to do anything like that. So this is a few miles a week. I think it's, first of
all, like something I think the normal humans she'll be able to do is run a mile decently.
Sprinting too, like a little bit of sprinting,
and I don't mean 100% over speed sprinting.
Even if this is as simple as, sprint this right away
is walk the corners kind of thing, and you did two laps.
That's pretty good.
You're gonna stay away from a lot of foot
and Achilles related injuries.
Andy, not surprisingly, we left nine questions
on the table getting through technically only
about three, but these were big ones.
So I'll just say thank you very much and I hope everybody enjoys this at least half as much
as I did and I'll see you back for round three.
Maybe we'll need to do this in person.
You got to come up with a reason to come to Austin, right?
I'll make it happen.
It can't be that hard.
I'll make it happen.
We'll commit to round three in person so we can get a workout in at the same time.
Yeah, yeah.
I'd love to see the spot too. All right, thanks Andy.
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