Huberman Lab - Improve Flexibility with Research-Supported Stretching Protocols
Episode Date: June 13, 2022In this episode, I explain the science behind limb range of motion and flexibility and how to increase them by using science-supported protocols. Flexibility is crucial for physical movements and can ...help prevent injuries, decrease inflammation, modulate physical and mental pain, impact exercise recovery speed and even potentially slow the progression of certain diseases. I explain the biology of flexibility, including the specific neural mechanisms that sense stretch and load (i.e., tension) on the muscles and limbs, as well as how specific brain regions like the insula combine those signals to ultimately control limb range of movement. I also provide science-based stretching and “micro-stretching” protocols that reliably improve limb flexibility with the minimum necessary time investment. I review all the details of those stretching protocols: how often to do them, for how long, their timing relative to other exercises, sets, the time between sets, measuring progress and more. All people, physically active or not, should benefit from the information and tools described in this episode. For the full show notes, visit hubermanlab.com. Thank you to our sponsors AG1 (Athletic Greens): https://athleticgreens.com/huberman InsideTracker: https://insidetracker.com/huberman Supplements from Momentous https://www.livemomentous.com/huberman Timestamps (00:00:00) Flexibility & Stretching (00:02:57) Sponsors: AG1, InsideTracker (00:07:22) Innate Flexibility (00:09:23) Movement: Nervous System, Connective Tissue & Muscle; Range of Motion (00:17:51) Golgi Tendon Organs (GTOs) & Load Sensing Mechanisms (00:20:20) Decreased Flexibility & Aging (00:22:38) Insula, Body Discomfort & Choice (00:30:02) von Economo Neurons, Parasympathetic Activation & Relaxation (00:42:00) Muscle Anatomy & Cellular ‘Lengthening,’ Range of Motion (00:47:16) Tool: Protocol - Antagonistic Muscles, Pushing vs. Pulling Exercises (00:51:57) Types of Stretching: Dynamic, Ballistic, Static & PNF (Proprioceptive Neuromuscular Facilitation) (00:59:36) Tool: Increasing Range of Motion, Static Stretching Protocol, Duration (01:05:56) Tool: Static Stretching Protocol & Frequency (01:13:55) Tool: Effective Stretching Protocol (01:17:12) Tool: Warming Up & Stretching (01:19:17) Limb Range of Motion & General Health Benefits (01:25:30) PNF Stretching, Golgi Tendon Organs & Autogenic Inhibition (01:31:23) Tool: Anderson Protocol & End Range of Motion, Feeling the Stretch (01:32:50) Tool: Effectiveness, Low Intensity Stretching, “Micro-Stretching” (01:41:33) Tool: Should you Stretch Before or After Other Exercises? (01:45:41) Stretching, Relaxation, Inflammation & Disease (01:51:37) Insula & Discomfort, Pain Tolerance & Yoga (02:00:36) Tools: Summary of Stretching Protocols (02:03:00) Zero-Cost Support, YouTube Feedback, Spotify & Apple Reviews, Sponsors, Momentous Supplements, Instagram, Twitter, Neural Network Newsletter Title Card Photo Credit: Mike Blabac Disclaimer
Transcript
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Welcome to the Huberman Lab podcast where we discuss science and science-based tools for everyday life.
I'm Andrew Huberman and I'm a professor of neurobiology and ophthalmology at Stanford School of Medicine.
Today we are going to discuss the science and practice of flexibility and stretching.
Flexibility and stretching are topics that I believe do not receive nearly as much attention as they deserve.
For most people, the topics of flexibility and stretching, bring to mind things like yoga,
injury prevention, or maybe even contortionism.
But it turns out that flexibility and stretching are features that are built into our basic body
plan.
Young children, young animals, and adults, and indeed older children and animals all stretch and all have
some degree of flexibility.
It turns out that having flexibility and our ability to stretch and the interaction
between stretching and flexibility are fundamental to how we move, our ability to learn new
movements.
Indeed, also to prevent injury will repair injuries and to offsetting and reducing inflammation
throughout the body.
In fact, today I'm going to share with you a remarkable set of studies that show that
stretching can actually adjust things like tumor growth.
This is work that was done by one of the major directors of the National Institutes of
Health.
Today's discussion will start with a description of the mechanisms, literally the cells and
the connections from a nervous system that mediate flexibility and stretching.
And I promise that I'll make that information accessible to you whether or not you have
a biology background or not.
Then with that information in hand, I'm going to present to you what the scientific literature
says about the best times and ways to stretch.
Everything right down to the detail of how long to hold a stretch, whether or not to hold a stretch at all,
because it turns out there are multiple kinds of stretching.
So you can imagine you have stretches where you hold the stretch
for a very long time and use as little momentum as possible.
And then there's also what's called dynamic and ballistic
stretching where you're literally swinging your limbs
trying to increase the range of motion.
I will explain the science and application of flexibility
and stretching in the context
of sports performance, whether or not you're engaging
in cardiovascular exercise or resistance exercise
or both, whether or not you're competitive athlete
or simply a recreational exercise or, as I am,
whether or not you are trying to increase your range
of motion and flexibility for longevity purposes,
or whether or not you're trying to do it
in order to access different parts of your nervous system because we'll soon learn today that your
ability to improve flexibility and need to engage in specific stretching exercises can actually
be used to powerfully modulate your ability to tolerate pain, both emotional and physical
pain.
So, this thing that we call flexibility and stretching is actually a vast landscape. We're going to simplify and organize all that for you today and by the end of today's
episode you're going to have a number of simple easy to apply tools that are grounded in the best
scientific research that you can apply for your specific goals. Before we begin I'd like to
emphasize that this podcast is separate from my teaching and research roles at Stanford. It is
however part of my desire and effort to bring zero cost to consumer
information about science and science-related tools to the general public.
In keeping with that theme, I'd like to thank the sponsors of today's podcast.
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Let's talk about flexibility and stretching.
Before we talk about the practices of flexibility and stretching, I'd like to just highlight
some of the features that are already built into your nervous system and into your body
that allow you to be flexible.
Some of us feel tighter than others, sometimes in specific limbs or areas of our body, some
people feel really loose and limber.
Some people even have what's called a hyper flexibility.
I, for instance, have a relative that can take her fingers and bend them back to the
point where they touch her wrist, and it always makes me cringe a little bit, but she
can do that without any pain.
She seems to have some hyper flexibility in her joints.
I do not have that feature.
Some of you may find that you are more flexible
than others naturally.
And some of you might be thinking,
you don't need to build an additional flexibility.
Well, I think by the end of today's episode,
you'll realize that almost all of us can benefit
from having some sort of understanding about flexibility
and having some stretching protocol
that we incorporate into our life,
if not just for physical performance reasons and for postural reasons, then also for cognitive
and mental reasons.
And I'll be sure to clarify what all of that means.
Right now I'd like to take a moment and just highlight the flexibility that you already
have.
For instance, if you were to move your arm behind your torso a little bit
and then sort of let go or stop exerting any effort in doing that, you would find that the limb
would return more or less to a position next to your torso, at least I would hope so.
Why is that? Well, it turns out that there are aspects of your nervous system, aspects of your
skeletal system, aspects of your muscles, and aspects
of the connective tissue that binds all of that together, that try and restore a particular
order or position to your limbs and your limbs relative to one another.
So that reflects a very specific set of processes, that it turns out are the same set of processes
that you use when you are trying to enhance flexibility and stretching.
So I'd like to just take a moment and review the basic elements of nervous system, muscle,
connective tissue, and skeletal tissue, bone that allow for flexibility and stretching.
And here we can point to two major mechanisms by which your nervous system
neurons, meaning nerve cells, communicate with muscles and those muscles communicate back to
your nervous system to make sure that your limbs don't stretch too far. They don't move too far
such that you get injured. And in addition to that, mechanisms that ensure that you don't overload your muscles too much
with weight or with tension or with effort and damage them that way.
Because it turns out that the second security mechanism of making sure that you don't overload muscles
can be leveraged toward increasing your flexibility almost immediately.
That's right. There are protocols and tools that I'll share with you that are going to allow you to vastly
improve your flexibility over time, but there are also mechanisms that allow you to quite
significantly increase your degree of flexibility in a very short period of time within just a
few seconds.
So let's establish some of the basic biological mechanisms.
In time we talk about biology or physiology, we're going to talk about structure, meaning
the cells and their connections and functions, what they do.
There are just a few names to understand.
You do not have to memorize these names.
The important thing that I'd like you to know is that flexibility and the process of stretching
and getting more flexible involves three major components.
Neural meaning of the nervous system, muscular muscles,
and connective tissue. Connective tissue is the stuff that surrounds the neural stuff and
the muscular stuff, although it's all kind of weave together and braided together in complicated
ways. Some of you may have heard of fascia. We're going to talk a little bit about fascia today,
although it's such an interesting tissue that's really deserving of its own episode.
fascia today, although it's such an interesting tissue that's really deserving of its own episode.
Fascial tissue, we're going to talk about some of the stuff
that surrounds muscles that really gives you your shape
and holds everything together and allows
for flexibility to occur.
So here's a key thing that everyone should know,
whether or not you're talking about flexibility or not.
Your nervous system controls your muscles.
It's what gets your muscles to contract.
So within your spinal cord you have a category of neurons, nerve cells, that are called
motor neurons.
To be precise, they are lower motor neurons because they're in your spinal cord.
We call them lower to distinguish them from the motor neurons that are in your brain
up in your skull.
Those lower motor neurons, hereafter,
I'll just refer to them as motor neurons.
If I wanna talk about the other kind of motor neurons,
I'll say upper motor neurons.
So if I say motor neurons,
I just mean the ones in your spinal cord.
Those motor neurons send a little wire or set of wires
out to your muscles, and that creates what's called
a neuromuscular junction, which just means
that the neurons meet the muscles
at a particular place.
Those neurons release a chemical.
That chemical is called acetylcholine.
Some of you may have heard about acetylcholine before.
Acetylcholine also exists in your brain
and does other things in your brain.
Mainly it's involved in focus and attention,
but at the neuromuscular junction,
the release of acetylcholine from these nerve cells,
these neurons onto the muscles,
causes the muscles to contract.
And when muscles contract,
they are able to move limbs by way of changing
the length of the muscle,
adjusting the function of connective tissue
like tendons and ligaments.
And for instance, if you're bringing your wrist closer to your shoulder,
that biceps muscle is contracting, it's getting shorter.
I mean, in reality, it hasn't gotten shorter overall.
It's just temporarily shorter, of course.
All of that is controlled by neurons.
And it's those motor neurons from the spinal cord that are really responsible
for the major movement
of your limbs by way of causing contraction
of specific muscles at specific times.
So the key thing to take away is that nerve controls
the contraction of muscles.
Now, within the muscles themselves,
there are nerve connections.
And these are nerve connections that arise
from a different set of neurons in the spinal cord
that we call sensory neurons.
The sensory neurons exist in a different part of the spinal cord
and they send a little wire or set of wires into the muscles.
And there's a particular kind of sensory neuron
that comes out of your spinal cord and into your muscles,
which are called spindle neurons.
They create, or they actually wrap around muscle fibers,
and quirk screw around them,
and give kind of a spring-like appearance
if for you aficionados out there,
these are intrafusal connections or neurons.
Intrafusal means within the muscle,
but you really don't need to know that
unless you're really curious about it,
or you're gonna become an neuroscientist
or you're in medical school or something,
these spindle connections within the muscle
that wrap around the muscle fibers
sense the stretch of those muscle fibers.
So now we have two parts to the system that I've described.
You've got motor neurons that can cause muscles to contract
and shorten, and we have these spindles
within the muscles themselves that wrap around the muscle fibers,
and that information is sent from the muscle
back to the spinal cord.
It's a form of sensing what's going on in the muscle,
much in the same way that you have neurons in your eye that sense light in your external environment. You have neurons in your ear that sense sound waves
in your external environment. You have neurons in your spinal cord that are sensory neurons that
are sensing the amount of stretch in the muscles. What happens is if a given muscle is stretching really far, those sensory neurons, those spindles
within the muscle, will activate and will send a electrical potential, literally a bit
of electricity along that wire's length into the spinal cord.
And then within the spinal cord, that sensory neuron communicates through a series of intermediate
steps, but to the motor neuron and make sure
that that motor neuron contracts.
Why would that be useful?
Well, what this does is it creates a situation where if a muscle is stretching too much because
the range of motion of a limb is increased too much, then the muscle will contract to bring
that limb range of motion into a safe range again.
Now, what determines whether or not a range of motion is, quote, unquote, safe or not,
is dictated by a number of things.
It's dictated by things that are happening in this kind of loop of neural connections
in the spinal cord and muscle.
It's also determined by what's going on in your head, literally in your mind, cognitively,
about whether or not the movement of that limb,
its increasing range of motion is good for you,
whether or not you're doing it deliberately,
whether or not it's bad for you,
and then there are also some basic safety mechanisms
that are put in there that really try
and restrict our limb range of motion.
Okay, so just to clarify, this whole thing looks like a loop,
and the essential components of the loop are
motor neurons, contract muscles, sensory neurons,
of which there are a bunch of different varieties.
In this case, what we're calling the spindles,
are sensing stretch within the muscles.
And if a given muscle is elongating
because of the increased range of motion of a limb,
those sensory neurons send an electrical signal into the spinal cord such that there is an activation of the motor neuron,
which by now should make perfect sense as to why that's useful. It then
shortens up the muscle. It actually doesn't really shorten the muscle, but
contracts the muscle that brings the limb back into a safe range of motion.
Okay, so this process is very fast. It was designed to keep your body together
and safe. It's designed to make sure that you don't, you know, take your arm and swing it behind
your torso and it just goes all the way back to the middle of your back. I mean, unless you're a
contortionist, you've trained that kind of level of flexibility. That would be terrible because
it could provide a lot of damage to the muscles and to the connective tissue and so forth.
So that's one basic mechanism that we want to hold in mind. This idea of a spindle that senses stretch and can
activate contraction of the muscles and shorten the muscles. The next mechanism I want to describe, and
once again, there are only two that you need to hold in mind for this episode.
This other mechanism has a lot of the same features as the one I just
described, but it has less to do with stretch. In fact, it doesn't have to do with stretch,
as much as it has to do with sensing loads. So at the end of each muscles, you have tendons,
typically, and there are neurons that are closely associated with those tendons that are called Golgi-Tendon
organs, right? These are neurons that are sensory neurons that sense how much load is on a
given muscle, right? So if you're lifting up something very, very heavy, these neurons are
going to fire, meaning they're going to send electrical activity into the spinal cord,
and then those neurons have the ability to shut down, not activate, but shut down
motor neurons and to prevent the contraction of a given muscle. So for instance, if
you were to walk over and try and pick up a weight that is much too heavy for you,
meaning you could not do it without injuring yourself and you start to try and
heave that weight off the ground. There are a number of reasons why you might not be able to lift it.
But let's say you start to get a little bit off the ground or you start to get some force
generated that would allow it to move.
But the force that you're generating could potentially rip your muscles or your tendons
off of the bone, right, that it could disrupt the joints and it could tear ligaments.
Well, you have a safety mechanism in place. It's these Golgi tendon organs, these GTOs, as they're called, that it could disrupt the joints and it could tear ligaments. Well, you have a safety mechanism in place.
It's these Golgi tendon organs, these GTOs, as they're called, that get activated and shut
down the motor neurons and make it impossible for those muscles to contract.
Okay, so on the one hand, we have a mechanism that senses stretch and can figure out when
stretch is excessive and when the system detects that stretch is excessive, it activates the contraction of muscles.
And then we have a second mechanism that senses loads.
And when tension or loads is deemed excessive by these circuits,
and remember these circuits don't have a mind, they don't go,
this is excessive, they just sense loads.
And when those loads exceed a certain threshold,
well, then those GTOs, those Golgi-10 in-ordid-send signals
into the spinal cord that shut down
your motor neurons' ability to contract muscles
so that you no longer can lift that heavy load.
So both of these are protective mechanisms,
but both of these can be leveraged
in a very logical way and in a very safe way
in order to increase your limb range of motion.
So there are a couple of things I wanna point out before going a little bit further into
how your nervous system controls flexibility and stretching.
And those key points are the following.
There are now dozens, if not hundreds, of studies, that show that a dedicated stretching practice
can improve limb range of motion.
Now, for many of you listening, you're probably saying, duh, but I think it's important to point that out that a dedicated stretching practice can increase
limb range of motion.
And as you'll soon learn, there are specific mechanisms that can explain that
effect.
The second point is one of longevity.
And when I say longevity, I don't necessarily mean late stage aging. We all undergo a
decrease in limb range of motion unless we do something to offset that decrease. And the current
number is vary from study to study. But if you look and mass, you look at all of those studies and
you basically find is that we start to experience a decrease in flexibility from about age 20 until about age 49, that's
pretty dramatic. And then, of course, it will continue after age 49. But basically, it's
a 10% decrease every 10 years. So we could say it's a 1% decrease per year, although it's
not necessarily linear. What do I mean by that? Well, it's not necessarily that on your 21st
birthday, you are 1% less flexible than you were on your 20th birthday
and it decreases by 1% per year.
Some of these changes can be non-linear.
So you can imagine the person who's doing just fine
in terms of flexibility between 20 and 30,
and then they get to 32,
and suddenly they've lost 5% of their flexibility.
Now, of course, there will be a ton of lifestyle factors.
If you're a regular practitioner of yoga,
if you have a dedicated stretching practice,
if you're doing other things to improve your muscle contractability, so you're doing
resistance training, it turns out can actually indirectly improve flexibility.
There are a number of different factors, but the key point is that maintaining some degree
of flexibility and maybe even enhancing range of motion and flexibility is of immense
benefit for offsetting injury provided it's not pushed too far.
There are a number of people who have pushed their limb range of motion so far that they
experience all sorts of injuries, both acute and chronic injuries.
Today, we'll also talk about how to avoid those scenarios.
Okay, so we've established that there are mechanisms within the spinal cord, muscles, and connective
tissue.
Those, remember, it's the motor neurons, the spindles, the GTOs, and, of course, the muscles themselves,
and connective tissue, tendons, but also other forms of connective tissue, that establish
whether or not a limb is going to stay within a particular range of motion or not, and whether or not a limb is going to be allowed by the nervous system to pursue or handle a given load, a
given tension.
There are also mechanisms that arrive to the neuromuscular system from higher up in the
nervous system, from the brain.
And those mechanisms involve a couple of different facets that are
really interesting, and I think that we should all know about. In fact, today I'm going to teach you
about a set of neurons that I'm guessing 99.9 percent of you have never heard of, including all
you neuroscientists out there, if you're out there, and I know you're out there, that seem
uniquely enriched in humans and probably perform essential roles in our ability
to regulate our physiology and our emotional state.
So within the brain, we have the ability to sense things in the external world, something
we call exter reception, and we have the ability to sense things in our internal world within
our body called interoception.
Interoception can be the volume of food in your gut,
whether or not you're experiencing any organ pain or discomfort, whether or not you feel good
in your gut and in your organs. That's actually, you know, kind of feeling, I feel great, I feel
say-ded, I feel relaxed. Those are all different forms of interoception. The main
brain area that's associated with interpreting what's going on in our body is called the insula,
INSULA.
It's a very interesting brain region. It's got two major parts. The front of it is mainly concerned with things like smell and to some extent vision and to some extent.
Other things that are arriving from the external world and combining with what's going on internally and making sense of that of all that, or at least
routing that information elsewhere in your nervous system to make decision. Like if you smell
something good to approach it, or if you smell something bad to avoid it. The front of the insula
is really doing all of that kind of stuff, along with other brain areas. The posterior insula,
the back of the insula that is, has a very interesting and distinct set of functions.
insula that is has a very interesting and distinct set of functions.
The posterior insula is mainly concerned with what's going on with your
somatic experience.
How do you feel internally and how is the movement that you happen to be doing
combining with your internal state to allow you to feel as I like to say the nervous system mainly batches things into yum
like oh this is really good for me. Yuck this is really bad for me and I need to stop or meh
This is kind of neutral. Okay, so this isn't about food
But we could say for most stimuli most senses whether or not they're senses of things internally or externally
Our nervous system is trying to make decisions about what to do with that information
And so it mainly batches information into yum.
I want to keep doing this or approach this thing or continue down some path of movement
or eating or staying in a temperature environment, et cetera, or yuck.
I need to get out of here.
I don't want any more of this.
I don't want to keep doing this.
This is painful or aversive or stressful.
And then, meh. So if it doesn't really matter, I can just kind of stay right here or not.
Yum, yuck and meh. Well, in your posterior insula, you have a very interesting population of
very large neurons. These are exceptionally large neurons called vaniconnimo neurons. These
are neurons that are, again,
unbeknownst to most neuroscientists
and they seem uniquely enriched in humans.
Chimpanzees have them and some other large animals have them.
So they're found in whales, chimpanzees, elephants,
and in humans.
But even though we are much smaller than most whales,
and even though we are much smaller than most elephants,
I mean, remember there are baby elephants.
As far as I know, they haven't bred up like mini elephants yet.
They seem to have a teacup version
of pretty much every dog breed.
You can look that up.
I certainly have mixed feelings about this notion
of trying to downsize everything to the point
where you could kind of like the pocket-sized bulldog,
I think of someday will arrive.
I'm not a fan of that kind of downsizing of different breeds.
But because there aren't T-Cup elephants
and T-Cup gorillas and T-Cup chimpanzees and so forth,
most all of those other species are larger than us.
They have these Van Economo neurons,
and we have these Van Economo neurons,
but we have in upwards of 80,000 of these things in
our poster in slut.
These other species tend to have somewhere in the range of a thousand to maybe 10,000 or
so.
Why is that interesting?
Well, these Van Economo neurons have the unique property of integrating our knowledge
about our body movements, our sense of pain and discomfort, and can drive
motivational processes that allow us to lean into discomfort and indeed to overcome any
discomfort if we decide that the discomfort that we are experiencing is good for us or
directed toward a specific goal. This knowledge turns out to be very important to keep
in mind because as we migrate this conversation toward the things that we can do to enhance flexibility
and stretching, you'll soon learn that there are moments within a stretching
protocol where you have the opportunity to either override pain and discomfort,
to kind of relax through it or push through it. There's a decision fork in the road there and I'll tell you which
fork in the road to take. Or to say, I'm not going to do that. I'm going to allow these
natural reflexes of the spindle to kick in and just essentially stop me from stretching
if a given limb isn't designed or shouldn't be stretched that far. So I'd like you to keep
these Van Economo neurons in mind. I should
mention they're named Vaniconimo because the guy Constantine Vaniconimo that
discovered them at the end of the 1800s, early 1900s, decided to name them
after himself as many scientists do, or certainly the neurologists and
physicians are famous for naming things after themselves. These Vaniconimo neurons
turn out to be very important to keep in mind as we embark on
our exploration of what sorts of stretching practices can be best applied to increase
flexibility.
Because whether or not you undertake a mild, moderate, or intense flexibility training, you will no doubt encounter a scenario at some point
where you will have to ask yourself, do I quote unquote, relax into this stretch or do
I try and push through just a little bit of discomfort.
And I'll explain how to gauge that decision in a very specific and ideally safe way.
And I'll give you some tools that will allow you to make that decision in the way that best preserves
the integrity of those neural circuits
that I described earlier and can keep you safe.
These vaniconnamo neurons sit in the exact position
that one would want to be able to evaluate
what's going on in the body,
in particular what's going on in terms of limb movements,
how that relates to our feelings of discomfort.
And then there's the other aspect
of these vaniconnomon neurons,
which is that these vaniconnomon neurons
are connected to a number of different brain areas
that can shift our internal state
from one of so-called sympathetic activation.
So this is a pattern of alertness and even stress,
sometimes even panic,
but typically alertness and even stress, sometimes even panic, but typically alertness and stress
to one of so-called parasympathetic activation, to one of relaxation.
Oftentimes, you'll hear that stretching should be done by relaxing into the stretch.
Well, what does it actually mean to relax into the stretch? Well, these vaniconnomon neurons
sit at this junction where they are able to evaluate
what's going on inside our body and allow us to access neural circuitries by which we can
shift our relative level of alertness down a bit or our relative level of stress down a bit
and thereby to increase so-called parasympathetic activation and to literally override some of those spindle
mechanisms, even the GTO mechanisms, but especially the spindle mechanisms at the neuromuscular
and muscular spinal junction.
And in that way, gently, subtly override the reflex that would otherwise cause us to contract
those muscles back.
The reason that's possible is because your brain has those other kinds of motor neurons,
the upper motor neurons that can both direct meaning control and can override lower motor
neurons.
I'll give you a brief example of this that you've already done in your life and that we
all have the capacity for.
What I'm referring to is the monosynaptic stretch reflex.
This is something that every first-year neuroscience graduate student learns, which is that if you
were to step on a sharp object with a bare foot, you would not need to make the decision
to retract your foot.
You would automatically do that, provided you have a healthy nervous system.
There are mechanisms in place that cause the retraction of that limb by way of ensuring that the proper muscles contract and other muscles do not contract.
In fact, that they fully relax. So in the case of stepping on a sharp object, like a piece of glass or a nail or attack,
you would essentially activate the hip flexor to lift up your foot as quickly as possible.
In doing so, that same neural circuit would activate a control lateral meaning opposite
side of the body circuit to ensure that the leg, the foot that's not stepping on the sharp
object would do exactly the opposite and would extend
to make sure that you don't fall over. All of that happens reflexively. It does not require any
thought or decision making. In fact, humans without any neocortex, literally, they're who are
discerbate, or an animal that doesn't have, when I say dis seribret, I mean, lack of cerebral cortex.
They can perform that because it's all controlled by circuits
that are basically below the brain
and in the spinal cord.
There's a little bit of activation of circuits
in the kind of deeper parts of the brain,
but basically you don't need to think
or decide in order to do that.
However, if your life depended on walking across
some sharp objects, let's say, let's make it a little less dramatic so it's not
like the diehard movie or something where you have to run barefoot across the
glass, although that's a pretty good example of what I'm describing here, but
let's say you had to walk across some very hot stones to get away from
something that you wanted to avoid.
You could override that stretch reflex by way of a decision made with your upper motor neurons,
your insula and your cognition and almost certainly those vaniconnamo neurons, which would
be screaming, don't do this, don't do this, don't do this, could shuttle that information
to brain areas that would allow you to override the reflex and essentially push through
the pain. And maybe even, in fact, even,
not experience the pain to the same degree or even at all. So these vaniconnomonarons
sit at a very important junction within the brain. They pay attention to what's going
on in your body, pain, pleasure, etc. And that includes what's going on with your limbs
and your limb range of motion.
They also are paying attention and can control the amount of activation, kind of alertness
or calmness that you are able to create within your body in response to a given sensory
experience. And as I mentioned before, they seem to be uniquely enriched in humans. They seem to be related to the aspects of our evolution that allow us to make decisions
about what to do with our body in ways that other animals just simply can't.
Before we go any further, I want to give you a practical tool that you can, of course,
use, but that will also give you insight and experience into your muscle spindle spinal cord circuit mechanisms.
So what I'd like you to do is if you're in a proper place to do this, you're going to stand with
legs straight, meaning knees not bent, and you're going to try and touch your toes, or for some of
you that's going to be very easy, and you might even be able to put your hands flat on the floor.
I don't have that kind of flexibility.
It's pretty easy for me to touch my toes.
I don't care if you round your back or not,
although ideally, I would say don't round your back,
not because it's bad to do so necessarily,
but just to try and keep this the same from trial to trial,
as it were.
So try and get a sense of what your range of motion is
in terms of bending over at the waist
while maintaining a flat back and trying to touch your toes or even touch the floor. Maybe
again, you can even go hands flat to the floor, maybe even far out in front of you.
Okay. Now what I'd like you to do is stand back up. And I'd like you to contract your quadriceps
as hard as you possibly can for about five to fifteen seconds.
Let's say ten seconds just to keep things more or less normalized.
This obviously is not a super controlled experiment.
So to contract your quadriceps for those of you that don't know, you're going to extend
your lower limb out, so this would be like kicking.
Although don't do it too quickly, you're going to kick out your foot.
You should feel your quadriceps contract on the top of your
thighs and you're going to try and consciously contract them as hard as you can.
Okay, typically if you want to point your toe back towards your near shin that's
also going to help somewhat to contract even harder and harder. Okay, so do
that for about 10 seconds. A lot of you will do this just while standing, contract contract, contract, okay, then release it. And then now go ahead and repeat that stretch where
you're trying to touch your toes or touch the floor. So this is again relying more
or less on hamstring flexibility among other things. Okay, what most of you will
find is that you have an immediate increase in hamstring flexibility or your
range of motion has increased. If you didn't experience that, then I would
encourage you to try and contract your quadriceps harder and longer, so maybe
20 or 30 seconds, and then try this so-called experiment again. Why would
contracting your quadriceps allow your hamstring flexibility to suddenly increase. Well, the way that our
muscles are organized is such that we have muscles that are antagonistic to one another. So our
quadriceps and our hamstrings work in sort of a push pull fashion, if you will. They can
antagonize one another. So when you move your heel towards your glutes, you are using your hamstring.
The hamstring obviously also does other things related to hip movement.
And when you lift your knee or when you extend your foot and contract your quadriceps, you
are essentially relaxing the hamstrings.
Now, of course, most movements involve both quadricep and hamstring in synchrony, and that synchrony
is really an elegant one.
But here we're more or less isolating the quadriceps from the hamstrings, at least, to the extent
that it can leverage these spindle stretch mechanisms.
What happens is when you contract your quadriceps hard, you are relaxing or releasing some of
the stretch that's occurring in those intrafusal spindle sensory fibers going into your spinal cord and as a consequence
you're able then to
stretch your hamstrings further or we can be more accurate and say that your range of motion about the hamstring and its related joints is greater
range of motion about the hamstring and its related joints is greater when you aren't engaging that spindle reflex which would cause the hamstrings to
contract. Okay, so if you are somebody who has tight hamstrings, there could be a
variety of reasons for that, but part of the reason is likely to be neural and
you can release that neural spindle reflex by contracting the opposite
antagonistic muscle, which in this case is the quadriceps.
The same thing is true and can be leveraged for stretching other muscles.
So for instance, if you're going to do a tricep stretch, the typical kind of overhead
where you grab your elbow and move it toward the midline of your body with the other hand,
using your opposite hand, well, you can do that.
And then I would suggest trying to flex your bicep, contract your bicep
that is while doing that.
And for most people you'll notice a increase in the tricep range of motion or ability to kind
of lean into or to relax into or to push that stretch, excuse me a little bit further.
Now for you physios out there and for those of you that have backgrounds in kinesiology, I want
to acknowledge, of course, there are other mechanisms that are coming into play.
There are actually neural connections within the joints themselves that are providing appropriate
receptive feedback, et cetera, et cetera.
But this is simply to illustrate that part of our range of motion is determined by these
spindle mechanisms that I spent some time focusing on earlier.
And indeed, this approach can be leveraged toward creating increased limb range of motion,
not just for the hamstrings, but for your quadriceps.
So for instance, if you have tight quadriceps, you can do the opposite.
You can contract your hamstring very intensely for, let's say, 10 seconds or 20 seconds or 30
seconds.
So that would take some conscious effort of bringing your heel up towards your glutes.
You could do that in a way that you're really trying to contract those muscles hard.
You'd have to use some deliberate hamstring activation there, meaning you have to use
those upper motor neurons and the other aspects of your upper brain power as it were to try and really contract your hamstring
says intensely as possible, then you would relax that. And then you would do your quadriceps stretch
again. And if you did a pre-hamstring contraction measurement of your quadricep flexibility,
and then you did a post hamstring contraction measure of your quadricep flexibility, almost certainly you would find
that that flexibility had increased.
Now of course, the muscle really didn't change much.
The tendons didn't change much.
What changed was the patterns of neural activation that were restricting you from in the first
case, stretching your hamstring.
We're having a, to be more accurate, we should say, to having a certain range of motion about the hamstring
and its related joints, and those brake mechanisms were removed.
And of course, then when you contract your hamstring, you're removing some of the neural
brakes, the spindle acting as a brake and inhibiting that quadricep range of motion.
Okay, so you can imagine this, and in in fact you can apply this for any number of different muscles.
The larger muscles and the sort of biceps triceps and hamstrings quadriceps are sort of the
simplest place to think about this and to apply it, but in theory and indeed in practice it really
works for all the various muscle groups. It's just sometimes harder to access these so-called
antagonistic muscle groups. Now we should take a moment and just discuss what actually happens as we get more flexible
in the short term and long term.
I just mentioned what happens in the short term.
Clearly those don't involve lengthening of the muscles.
It's not like the muscles slide along the bones or that the tendons really stretch out
that much more than they had prior to that kind of exercise.
But it is the case that if people stretch consistently
over a given period of several weeks or more,
that there are changes in the muscles.
This gets a little bit tricky in terms of nomenclature
and I just wanna highlight that
because I think that a number of people
get frustrated and confused, in
fact, when we talk about muscles getting longer.
The whole concept of a muscle getting longer isn't really in keeping with reality, but there
are elements within the muscles that can change their confirmation.
So to get a little bit detailed here, and we won't spend too much time on this, but I
just want to acknowledge this for those of you that are interested in neuromuscular physiology and
how it relates to flexibility.
You have your muscle fibers, and then you have your so-called myofibrils.
So you can imagine kind of a single fiber, and that fiber, of course, will get input from
those motor neurons.
And then within those fibers, you have what are called sarcomeres.
And you can kind of think about sarcomeres as little segments.
Kind of like the segments of bamboo.
If you ever look at bamboo, it's not just one big stalk.
It's got those little outpouchings along the way that gonna break up the, what would be
just one big stalk of bamboo into different segments, but they're all connected.
The sarcomeres are somewhat like that.
And within the sarcomeres you have
a couple of different components. One thing is called myosin, which is like a thick layer,
and then the other is actin. And those are interdigitated as we say. They're kind of connected
to one another, kind of like if you put your fingers together from your two hands, if
you put your fingers in between one another, that's interdigitated literally, interdigitated in this case, so pun intended.
And that myosin and actin kind of move relative
to one another and they have a lot to do
with your ability to contract muscles.
When we stretch muscles,
when we go through a stretching practice,
there are a number of things that change,
some neural, some related directly to connective tissue,
but also it appears from really nice work mainly done from McGill University.
I'll provide a link to a couple of these studies if you want to dig more deeply,
that change the confirmation, the relative size and spacing of some of these things
like sarcomeres and the way that myosin and actin kind of work together.
But we don't want to think of muscles as lengthening.
We can, however, think about the resting state of a muscle being slightly different or indeed
very different than the resting state of a muscle of somebody or of a limb that has not
undergone regular flexibility training.
So that's as much time as I want to spend on that because we could spend an entire hour
getting right down into the details.
But I do want to emphasize, however,
that muscles have different parts.
They have fibers, they have sarcomers,
they have mice, and they have actin.
But the idea of making our muscles longer,
that reflects a number of processes that occur basically
within an existing muscle length.
The length of our muscle bellies and where our insertions are,
relative to our connective tissue in our limbs,
is genetically determined.
Some people have, for instance, a bicep that goes all the way
from the crooked their elbow up to their shoulder.
And some people can, if they were to put their arm
at a 90 degree angle, could put two or three fingers between their bicep and their elbow.
They have a, we can say, a shorter bicep, relatively shorter.
Now, the reason I mentioned these highly detailed cellular mechanisms is because
as we start to embark on different protocols for using stretching to increase flexibility
in range of motion, we need to ask ourselves,
what is preventing our ability to extend range of motion?
Is it the spindle, right?
Is it because the muscle is stretching too much?
Oftentimes it can be because of that and or because of a sense of pain
or simply a sense that the muscle is not in a position that it's been in before,
that's unrelated to pain or to spindle activation.
And oftentimes it can be related directly
to these changes in the confirmation of myocin and actin
and within the context of the sarcomeres.
Now, of course, you can't peer into
or sense your individual sarcomeres.
However, you do have neurons that innervate these areas and that send that sensory information back into the spinal
cord and up to your brain to interpret. So you'll find that as we move along,
there are specific adjustments that you can make at the both the macro level,
meaning how much movement to insert into your stretching. Is it going to be a static or a
dynamic or even a ballistic stretch? Or for instance, at the micro level that even just a slight sub-millimeter or millimeter increase
in the stretching of a given muscle and it related tissues can translate into an increased
range of motion performance. As a quick but relevant aside, I thought I'd share with you something
useful that's also grounded in this notion of antagonistic muscles.
So for those of you that do resistance training, whether or not it's with body weight or with physical weights or machines, what have you, you may have found that if you, let's say, were to do three sets of a pushing exercise.
So this could be push ups. This could be bench presses. this could be shoulder presses, something of that sort.
And then later in the workout, you were to do, let's say, machine pull downs or pull ups
or chin ups of some sort, so a pulling exercise.
Typically, what you would find is if you were to do what's often called straight sets,
so you would do three sets of pushups, let's say with two minutes of rest in between, that
you might be able to get a certain number of repetitions on the first set.
Let's just for sake of example, let's say you can get 10 repetitions on the first set, and then you get
eight repetitions on the second set, and then you get six repetitions on the third set with two minutes in between.
And then you would move on at some point to your pulling exercises. And similarly, let's say you were doing chin ups or pull downs and you would get 10 repetitions,
rest 2 minutes, 8 repetitions, rest 2 minutes and 6 repetitions.
Okay, fine.
Well, typically what people discover is that if they interleave their pushing and pulling
exercises, provided they do that for muscles that are antagonistic to one another. So in this
case pushing with the chest shoulders and triceps for the pushing exercises and pulling
with the back and biceps and of course there are other muscles involved as well. But because
those muscle groups are at least in part antagonistic to one another, what people often find is that
if they were to say do their pushing set, get 10 repetitions, then move to a pulling
set after just say 60 seconds and perform that pulling set, then go back to the pushing
set, then go back to a pulling set, push, pull, push, pull, in other words, interleaving
their sets, even if they were to maintain the same amount of rest
between sets of pushing and sets of pulling, what they discover often is that the
drop in the number of repetitions that they get is somewhat offset. So rather than get 10,
8, 6, as it were with the straight sets, it will be 10, 9, 8. So what this means is not that you're increasing the total rest time to four minutes between
sets, because then of course it wouldn't be equivalent.
But rather that while maintaining the same amount of rest between sets for this same muscle
group, by going from push, pull, push, pull of antagonistic muscles, you're able to have improved performance.
And the reason for that has everything to do with what we were describing before, which
is that typically if you were to do push set, rest, push set, rest, push set, rest, well,
in between those sets, and in fact, actually during those sets of pushing, the pulling muscles
that would be involved in the chin-ups or pull downs, etc, are actually
relaxing or at least are being released of some tension, including the activation of the spindles,
among other things. So that's a long-winded way of saying that interleaving push and pull of
antagonistic sets can leverage some of the same neural
circuits that we're talking about leveraging for sake of increasing flexibility.
Now, I offer this to you as a tool that you can try.
One of the challenges with using this tool, however, is that you often have to occupy multiple
sites within the gym.
You know, if you're doing this at home and you have your own gym, that's one thing.
If you're doing this in a gym where you have multiple pieces of equipment, well, then
you become that person who has essentially taken over some small corner or multiple corners
or machines within the gym.
And oftentimes you'll find that you'll walk back to a machine or you'll walk back to a
given resistance exercise and someone has now taken it over and the whole thing can
be thrown off.
So it takes a little bit of orchestrating in order to do properly, but in general, what
people find is that this can allow you to enhance performance overall of these individual movements.
Again, while maintaining the same amount of rest, and even if you choose not to do this,
I encourage you to pay attention to this as a concept because, again, it's leveraging
this idea of antagonistic muscles, flexors and
extensors, antagonistic neural relationships between the spinal cord mechanisms that control
one set of muscles and activating those muscles, allowing the opposite antagonistic muscle
to relax and therefore to perform better on its next set.
So now I'd like to shift to the question of what types of stretching can and should we
do to increase limb range of motion.
If our goal is to do that in the most efficient way possible, because I realize that most people
don't have endless amounts of time to dedicate to a stretching practice.
And even for those of us that do, I'm sure that you want to get the most outcome for a given
effort.
And what are the modes of stretching that are going to allow us to increase our flexibility
and limb range of motion most safely?
Now, there are a number of different types of stretching or methods of stretching.
Broadly defined, we can describe these as dynamic, ballistic, static, and what's called
PNF stretching. PNF stands for proprioceptive neuromuscular facilitation,
and it involves and leverages many of the mechanisms
that I described you earlier.
The first two dimension, dynamic and ballistic stretching,
both involves some degree of momentum,
and can be distinguished from static and PNF type stretching.
Now, to distinguish dynamic stretching from ballistic stretching,
I'd like to focus on this element of momentum.
Both involve moving a limb through a given range of motion.
In dynamic stretching, however, it tends
to be more controlled, less use of momentum,
especially towards the end range of motion.
Whereas in ballistic stretching, there tends to be a bit more swinging of the limb
or use of momentum. So I invite you to visualize what dynamic and ballistic stretching might
look like in your mind. You can even try it if it's safe for you to try it. You could imagine
you're swinging your arm up overhead as much as possible and bringing it down. I'm doing this
because I'm seated as kind of ridiculous movement to do well seated or perhaps at all. But for instance, you can
see dynamic and ballistic stretching anytime someone for instance is holding onto something
with one arm or maybe not holding on and swinging out their their foot. So essentially getting
movement about the hip joint and you'll notice that some people raise it up and pause it and bring it down. That's one form of dynamic stretching, whereas others will swing it up and sort of
let it carry itself a bit further, do the momentum at the top of the movement and then just
let it drop back down or maybe even control the descent. There is an enormous range of
parameter space here or variables that one could imagine. And there's just simply no way that we could subdivide all those.
But again, dynamic and ballistic stretching both involve movement.
So we have to generate some force in order to create that movement.
Ballistic stretching involving a bit more momentum or sometimes a lot more momentum,
especially at the end range of motion.
Now both of those are highly distinct from static stretching, which involves holding the end range of motion. Now both of those are highly distinct from static stretching, which
involves holding the end range of motion, so minimizing the amount of momentum that's
used. So to stay with a simple example that we are all now familiar with from our earlier
discussion, slowly bending over at the waist and trying to touch your toes, or putting your
hands to the floor, and then holding that end position before
coming up in a slow and controlled way such that you reduce the amount of momentum to
near zero would be one example of static stretching.
Static stretching can be further subdivided into active or passive, right?
There are different names for these kinds of approaches.
You can hear about the Anderson approach or the John Deere approach.
You can look these sorts of things up online.
And again, people tend to name things after themselves.
So some of these are proprietary, religious, specific programs.
I'm not focusing on those.
Others come to be named after the physiologists or the practitioners
that initially popularize them.
As is always the case, there's always a naming and renaming and claiming of territory with these things.
For the time being, I'd like to just emphasize
that static stretching can be both active
where there's a dedicated effort on the part of the stretcher,
you to put force behind the hold to kind of extend
or literally to extend the range of motion.
And then there's also passive static stretching in which it's more of a relaxation into a further
range of motion.
And that can be a subtle distinction.
And there are other ways in which we can further distinguish active and passive static
stretching.
But nonetheless static stretching involves both those types of elements active and passive,
but is really about eliminating momentum.
And then there's the PNF, the proprioceptive neuromuscular facilitation.
And proprioception has several different meanings in the context of neuroscience and physiology
to just keep it really simple for today.
Properioseption involves both a knowledge and understanding of where our limbs are in
space and relative to our body, typically relative to the midline.
So the brain is often trying to figure out where our limbs are relative to our midline
down the center of our body.
And we know where our limbs are based on so-called proprioceptive feedback.
So that's feedback that comes from sensory neurons.
Right.
Now you know from sensory neurons. Right. Now you know what
sensory neurons that are essentially monitoring or responding to events within the joints,
the connective tissue, and the muscles. And within the deep components of the muscles,
like the spindle reflex and within the tendons like the GTO, the Golgi tendon organ. So
and within the tendons like the GTO, the Golgi tendon organ. So, PNF type stretching leverages these sorts of mechanisms,
these neural circuits.
By way of, for instance, you would lie on your back,
and if your goal is to increase your hamstring flexibility,
and the flexibility and range of motion
of other related muscle systems,
you might put a strap around your ankle and
pull
That muscle where I should say excuse me that limb towards you. You're not gonna pull the muscle towards you
You can pull the limb your ankle towards you to try and get it sort of back over your head and then
progressively relaxing into that or maybe even putting some additional force to push the end range of motion and then
maybe even putting some additional force to push the end range of motion and then relaxing it
and then actually trying to stretch that same limb
or increase the limb range of motion without the strap.
Sometimes these are assisted by other people.
So people will even use loads.
Sometimes they'll even use machines.
There are a number of different apparatus
that have been designed for this.
Sometimes it'll involve a training partner.
There's a huge range of PNF protocols and those protocols can be done both by oneself,
with or without straps, with machines, with actual weights, or with training partners. If you're
interested in the variation of exercises to say target your hamstrings versus your quadriceps,
versus your shoulders, versus your quadriceps versus your shoulders versus
your chest muscles, etc. Your neck muscles and so on. There is an enormous range of information
on dynamic ballistic static and PNF stretches for all the various muscle groups. And I should say
there's some excellent books on those topics. There are also some excellent videos on YouTube
and elsewhere. Nowadays it's pretty easy to find exercises that allow you to target specific muscle groups.
Again, I encourage you to be safe in how you approach this.
I would encourage you also to pay attention to the information that soon follows as to what
sorts of protocols one would use to apply those exercises.
But the number of exercises and the availability of those exercises for
targeting different muscle groups with these four different kinds of stretching is both
immense and fortunately, thankfully, immediately accessible to all of us often at zero cost.
So specific exercises to target specific muscle groups aside, we've now established that there
are four major categories of stretching, or at least those are the four major categories I'm defining today.
And we can further divide those categories into which are the ones that are going to be
most effective for increasing range of motion in the long term, not just in one individual
session.
And there have been a number of studies exploring this.
I can list out at least four, and we'll put those four as a kind of a cluster under one
heading in the show note captions that arrive at essentially the same answer, which is that
for increasing limb range of motion, it does appear that static type, including PNF, but static
type stretching is going to be more effective than dynamic and ballistic
stretching. So at least to my mind, this is good news. Why is it good news to me? Well, while
dynamic and ballistic stretching can be immensely useful for improving performance of specific
movements, in particular, in the of particular sports, like tennis or
in sprinting or frankly for any sport, they do carry with them a certain amount of risk
because of the use of momentum.
So you don't need to be highly trained in order to perform them.
In fact, there is a place and we will describe when one would want to apply dynamic or ballistic
stretching.
I'll just give give away for now.
I think that most physios out there,
and certainly the ones that I spoke to,
Dr. Andy Galpin, Dr. Kelly Staret,
and a few others point to the fact that
doing some safe dynamic and ballistic stretching
prior to say a resistance training session,
or maybe even prior to a cardiovascular training session,
can be useful, both in terms of range of motion effects and in terms of neural activation effects.
I don't want to use the words warm up because warming up is typically associated with increasing
corbauti temperature, as it should be, but for engaging the neural circuits and becoming familiarized with the neural
circuits that you're about to use in other movements, while also increasing the range of
motion of the joints involved in those movements so that you can perform them more safely and
more confidently.
So I'm certainly not saying, I want to repeat, I'm certainly not saying that dynamic and
ballistic stretching are not useful.
They absolutely are.
But in terms of increasing limb range of motion
in the long term of truly becoming more flexible as opposed to transiently more flexible,
static stretching, which includes PNF, appears to be the best route to go. So if your goal is to
increase your limb range of motion for a given muscle group or perhaps for all muscle groups.
Although, you can imagine that would be pretty tough.
I mean, you're not going to spend time, I could imagine working on your tongue muscle control
or neck muscle control and every muscle control.
But most of us want to reduce so-called tightness in their quotes and increase limb range
of motion for certain muscle groups.
And it appears that the best way to do that
is going to be static stretching of some kind,
which raises the question of how often
to do that static stretching and how long
to hold those static stretches.
And we can also ask the question,
we should ask the question, where to hold
those static stretches.
Is it always a good idea to hold those static stretches
at the end or the point
of maximal range of motion? We're going to address that now. There's some terrific
science around this. A slightly older study, but nonetheless, a powerful one because it
provided a foundation for a lot of subsequent work, which basically served to just confirm
the answer they got here, is a study from Bandy at all. The title of this study is the effect of time and frequency of static stretching on the
flexibility of the hamstring muscles.
It's a study involving 93 subjects, so 61 men, 32 women ranging in age from 21 to 39
years.
A broad demographic who had limited hamstring muscle flexibility, here I'm paraphrasing,
and randomly
aside to one of five groups. So the four stretching group stretch five days per week,
for six weeks, the fifth group, which served as a control, did not stretch. The results clearly show
that quote, the change in flexibility appeared to be dependent on the duration and frequency
of stretching. This is great. This tells us that stretching for a given amount of time scales with the amount of
limb range of motion improvement that one will see.
There were many interesting findings within this study, but the one that I'd like to highlight
most is, quote, the results of this study suggest that a 30-second duration is an effective
amount of time to sustain a hamstring muscle stretch in order to increase range of motion.
No increase in flexibility occurred when the duration of stretching was increased from
30 seconds to 60 seconds, or when the frequency of stretching was increased from one to three
times per day.
Okay, so now we're starting to lay down some parameters.
What this study reveals and what subsequent studies tell us and we will get into those subsequent
studies is that ideally one would do static stretches that are held for 30 seconds.
Perhaps more in certain instances and I'll explain when that can be useful, but here holding
those stretches for more than 30 seconds did not turn out to be additionally useful. So if
you're going to stretch your quadricep, for instance, and you're going to hold that
stretch in static fact, remember, not using momentum, and you can use the mental tricks
of either trying to push through the pain, which I don't recommend necessarily. I think
that makes us prone to injury or to relax into the stretch, but
nonetheless providing some force, typically with the with a hand in order to pull your
ankle back.
If you're doing a quadricep stretch, some people might do this on the edge of a sofa.
Remember, there are a lot of different exercises and ways to do this that you can explore elsewhere.
Well, holding that static stretch for 30 seconds appears to be sufficient to stimulate an increase in limb range of motion over time.
Again, these are protocols that were used repeatedly over time
and we'll talk about how often to repeat them
in order to get maximum effect.
But 30 second holds for static stretches
is the number that I think we want to focus on
and that most of us are going to want to utilize.
So now let's explore how many sets of static stretching
one ought to do in
order to get a maximum range of motion improvement while not placing us into a system that's
going to create injury, nor a situation where we have to be constantly stretching throughout
the day, because again, most of us don't have time to do that. This issue of sets is an
important one. In the context of cardiovascular exercise,
we've talked about the data that support the fact that doing at least 150 and ideally,
as much as 200 minutes per week of zone two cardiovascular exercise is very useful for cardiovascular
health and for other aspects of health. And of course, there are other aspects of cardiovascular
exercise that can be layered onto and into that. That can be useful like 90 second maximal sprints, etc.
Discuss this a lot in the episode with Dr. Andy Galpin and on our episode about endurance.
And we also talked about sets in the context of strength and hypertrophy building muscle size and or strength in the episode about that.
And in particular, in the episode with Dr. Andy Galpin.
And there, we could also arrive
at some specific parameters.
And it's gotten to vary, of course, between individuals, depending on how hard you train,
whether or not you take sets to failure, your repetition range, et cetera.
But in the context of strength and hypertrophy building, we arrived at a approximately six,
maybe as many as 10 sets per week per muscle group.
Some of that work is done as direct work to a given muscle group, some of that work is done as direct work
to a given muscle group, some of that work is indirect.
So doing certain pulling exercise, of course, will target the latissimus dorsi muscles,
but also the biceps.
So if that doesn't necessarily mean you have to do 10 sets for the biceps and for the
lat, sometimes you're getting some indirect work, etc.
All of that was delineated in the episode with Dr. Andy Galpin.
And we arrived at those numbers of sets according to the same criteria that we will apply here.
What is the minimum number of sets both to maintain and to improve a given mode of performance?
Strength and hypertrophy or cardiovascular health, again, to either maintain or improve.
And we can do the same thing for improving or maintaining range of motion.
Because as I mentioned earlier, the data points to the fact that if we don't do some dedicated
work to improve range of motion over time, we will lose our flexibility and limb range
of motion over time just by virtue of the fact that we're not doing anything to offset that.
So whether or not you want to maintain,
reestablish or gain limb range of motion,
static stretching of holds of 30 seconds appear to be best.
Now the question is how long should you do that
and how many sets should you do that
and how many times a week should you do that.
And to answer those questions, I'm gonna turned to what I think is a really spectacular review
This was a review that was published in the year 2018
So it's fairly recent first author Thomas it wouldn't Thomas last author paulma
We'll put a link to this in the show note caption the title of the paper is the relation between stretching typology and stretching duration the effects on range of motion
It's a very straightforward title is the relation between stretching, typology, and stretching duration, the effects on range of motion.
It's a very straightforward title.
This is a review article that explored
a number of different studies,
had criteria for whether or not those studies
could be evaluated in the context of the questions here,
had some quality standards and some other standards
that they applied.
And basically, window down, large collection of studies to a remaining 23 articles that
were able to be considered, quote, eligible and included in the quantitative synthesis
done here.
So key points from that quantification and synthesis done in this paper.
First of all, and I quote, all stretching typologies showed range of motion improvements
over a long term period.
However, the static protocols showed significant gains
with a p-value lesson .05,
which means a probability that cannot be explained
by chance alone when compared to ballistic or PNF protocols.
So again, what we're hearing is that static stretching
is the preferred mode for increasing limb range of motion.
Although here they make the additional point that static stretching might even be superior
not just to ballistic stretching, but also to PNF protocols.
Because before, as you may recall, there was a distinction between ballistic and dynamic
and static and PNF.
And so here it appears again that static stretching
is sort of rising to the top of the list
as the optimal approach relative to all other
stretching approaches,
at least in the context of increasing limb range of motion.
The authors go on to say time spent stretching per week
seems fundamental to illicit range of movement improvements when stretches are applied for at least or more than five minutes per week.
Okay, this is critical. This is not five minutes per stretch. Remember, 30 seconds per static stretch, but at least five minutes per week.
Whereas the time spent stretching within a single session does not seem to have a significant effects for range of motion gains. If this is getting confusing, I'll make sure that you
soon understand exactly what we can export from these conclusions.
The data indicate that performing stretching at least five days a week.
Now some of you may already be groaning for at least five minutes per week. Okay, so five days
per week, that's a lot, but at least five minutes per week,
five minutes per week is not that much.
Using static stretching, maybe beneficial to promote
range of motion improvements.
Okay, I've read this study in detail now.
They highlight again the reduction in flexibility
that occurs from 20 or 49 years of age and so on,
how acute bouts of short-term stretching
up to three weeks
can improve stretch tolerance.
I think that's a key point that in the short-term,
the first three weeks have embarking on a stretching
and flexibility program, much of the improvements come
from the short-term neural improvements that we talked about before
of inhibiting the spindle reflex and so on
and also a stretch tolerance,
a comfort with doing the movements
and maybe even a comfort in overriding
some of the pain mechanisms.
I'll talk a little bit more about that in just a bit and the particular utility of yoga,
something that I don't often practice, but that after reading this article that I'll
mention in a little bit, I'm considering perhaps taking up some form of yoga protocol.
Now, I've already highlighted some of the key takeaways from the study, namely, that we
need to get at least five minutes per week of static stretching per muscle group. And based on
the previous paper that we talked about, we need to divide that five minutes into sets of 30 seconds
each. And as I mentioned earlier, it doesn't seem to be the case that you can do all of that
in one day, unfortunately.
It does seem important that the frequency of stretching practice distributed throughout
the week is important.
So let's talk protocols.
We are now talking about doing static stretching, so holding, so limiting momentum and holding
a stretch for 30 seconds per set.
We're talking about trying to achieve five minutes per week of those static holds,
but that we can't do it all in one session
because the frequency of sessions
distributed throughout the week correlates
with the improvements in limb range of motion.
So what this means is that we should probably be doing
anywhere from two to four sets of 30-second static hold stretches
five days per week or some variant thereof. And I do say some variant thereof because it turns out
that even though there was that earlier study that we talked about that holding a stretch for
more than 30 seconds, in that case 60 seconds, didn't turn out to be additionally beneficial. It appears that if you do hold those stretches for 60
seconds per static stretching set, for instance, you can get away with stretching
fewer days per week overall. So in order to make this as clear as possible,
because I do realize there are a lot of parameters, and you might be asking,
why didn't you just make me a list of the exact things I should
do? Well, it doesn't work that way because once you understand the mechanisms and once
you understand your particular goals, this information is designed for you to be able to construct
a stretching program that is tailored to your specific goals.
If I just gave you the stretching program that I'm doing, or I should say that I'm soon
to be doing, because I'm soon to be doing one, based on the research for this particular episode.
Well, that wouldn't be beneficial for you.
Because for instance, if you have very flexible hamstrings,
but not very flexible quadriceps,
or you are somebody who is engaged in sports,
or not engaged in sport,
what you need to do is going to vary somewhat.
So what would effective stretching protocol look like?
We're all trying to improve limer range of motion for different limbs and different muscle
groups.
But just by way of example, and it's because the one we've been using, let's talk about
hamstrings for the time being.
This could of course be applied to other muscle groups.
Let's say you want to improve hamstring flexibility and limb range of motion about and around
the hamstring and involving the hamstring. You would want to do three sets of static stretching
for the hamstring. Again, easy to find such exercises on the internet. You would
do that by holding the stretch for 30 seconds, resting some period of time,
and doing it again, holding for 30 seconds, resting some period of time, and doing it again, holding for 30 seconds,
resting some period of time, and then holding it for 30 seconds. That would be one training session
for the hamstrings. I have to imagine that you'd probably want to stretch other muscle groups as well
in that same session, although at least as far as I could tell, there were no data pointing to the
fact that you couldn't do your hamstring stretching one part of the day and your quadriceps stretching,
another part of the day, but presumably you're going
to want to combine your flexibility training into one single session.
So three sets of 30 seconds each, get 90 seconds, and you would do that ideally five times
a week or maybe even more, because it does seem like frequency distributed throughout the
week is an important parameter.
Now one thing that we have not highlighted or at least described is how long to rest
between stretching sets.
And despite my efforts, I could not find research back information that pointed to whether
or not 30 seconds of rest for every 30 seconds stretching or 60 seconds rest
for every 30 seconds stretching was ideal.
I think it's reasonable to assume
that doubling the amount of time
for the interleaving rest would be appropriate
or at least doable.
If anyone out there has knowledge about rest
between stretching sets and has some physiology
or some biology or some experiential information
as to why a given ratio of duration of static stretch
to rest in between static stretch sets ought to be used.
Please put it in the comments on YouTube
that'd be a terrific way for us to get that information.
I'd love to do any follow-up to links that you provide
and so on.
But now we're starting to build into a protocol
that is backed by the scientific data.
Three sets of 30 seconds of Holt done five times
or maybe even six times per week.
One thing that did show up in my exploration
of the peer reviewed research
is this notion of warming up for all this.
We haven't talked about that yet.
In general, to avoid injury,
it's a good idea to raise your core body temperature a bit
before doing these kinds of stretches,
even these static stretches,
which we can sort of ease into
and don't involve ballistic movement by definition.
And the basic takeaway that I was able to find was
that if we are already warm from running or from weight training
or from some other activity, that doing the static stretching practice at the end of that weight
training or cardiovascular or other physical session would allow us to go immediately into the
stretching session because we're already warm, so to speak. Otherwise, raising one's core body temperature by a bit, by doing
five to seven, maybe even 10 minutes of easy cardiovascular exercise or calisthenic movements,
provider, you can do those without getting injured. Seems to be an ideal way to warm up the body
for stretching. We should be warm or warm up to stretch, although those warm-ups don't have to
be extremely extensive. And then just by way of logic, doing the static stretching after resistance training or
cardiovascular training seems to be most beneficial.
In fact, and unfortunately, we don't have time to go into this in too much detail today.
I was able to find a number of papers that make the argument that static stretching prior
to cardiovascular training and maybe even prior to resistance training can limit
our performance in running and resistance training.
I realize that's a controversial area.
You have those who say, no, it's immensely beneficial.
You have those who say, no, it inhibits performance and those that say, no, it's a matter of how
exactly you perform that static stretching and which muscle groups and how you're doing
this and how much time in between static stretching and performance. But to leave all that aside, doing static
stretching after some other form of exercise. And if not after some form of exercise after a
brief warm-up to raise your corbati temperature, definitely seems like the right way to go. Now for
some of you out there, and I confess for me as well, doing something
five days a week seems like a big commitment, even if that commitment is one to only do three
sets of 30-second static stretches. I say this because you've got the warm-up. I generally like to
bring a kind of a focus and dedication to a practice. And of course, because when doing these
kinds of protocols, it's likely that you're not just stretching
your hamstring, so it's not just 90 seconds of work with a minute of rest in between, but
very likely that you're also doing quadriceps stretching and also doing stretching for the
shoulders and stretching for the back and the neck and so on.
And so that entire session is going to take some time.
And five days a week is a pretty serious commitment for most, especially for those of us that
don't exercise or do athletics for a living, which I don't.
So there is some evidence from the literature that one can get away with, or I don't even
know that we should think about it as getting away with, but that one can do longer-hold
static stretches of up to, say, 60 seconds, but do fewer total sessions per week.
So rather than three 30-second static holds, doing 360-second static holds, and doing those
every other day.
And there really hasn't been a systematic exploration of this.
The article that I was referring to just a few moments ago, this analysis of the 23 articles
was combined into this enormous set of tables and some really
quite nice graphs that you're welcome to look at since we're going to provide a link to
the study.
There are a couple of key takeaways that I want to mention that are separate from this
issue of how long the stretch and how often.
First of all, they describe in their discussion that there were improvements in range of motion,
independent of whether or not people did
static stretching, active stretching, passive stretching,
ballistic stretching, or PNF stretching.
So all of those forms of stretching
will improve limb range of motion.
This is essential to point out,
and I wanna emphasize this,
static stretching however,
gave the greatest degree of gains in limb range of motion. And on average, they saw a 20.9% increase, but
some of the other increases they observed were also quite substantial. So, ballistic stretching
can also provide some pretty impressive limb range of motion improvements. However, they tended to be in the range of,
here they point out, 11.65% increase,
or in the case of PNF, a 15% increase.
So it appears that the greatest improvements
in limb range of motion for your time spent,
and effort spent, is going to be this minimum
of five minutes per week to elicit a significant response
with five days being the minimum weekly recommended frequency
to achieve significant range of motion improvements.
I confess this was pretty surprising to me
when I compare flexibility training to say
resistance training for strength and hypertrophy.
I've had the experience and I know that other people
have the experience and I think Dr. Andy Galpin would probably agree that provided one trains hard enough and appropriately that
you don't need to train resistance training five days a week in order to get significant
improvements in strength and hypertrophy.
Some people might need to, but you can get a lot of positive results in those variables
with less frequent training, certainly with three or four days a lot of positive results in those variables with less frequent training,
certainly with three or four days a week of training.
And for cardiovascular training, I'm not aware of anyone having tested whether or not one
very long run each week can actually increase cardiovascular fitness and you're not doing anything
else. So though, I have to imagine you probably see some improvement compared to not doing anything.
But most people are doing repeated training sessions
of cardiovascular strength training. Not a lot of people are doing five days a week of strength
training, at least that I'm aware of. Some people are, but most people I think are not, and
some people are doing five or more days a week of cardiovascular training. I'm guessing that
most people are not doing five days a week of dedicated
static stretch range of motion directed training, but it does appear that that frequency about
the week, getting those repeated sessions, even if they are short for an individual muscle
group, turns out to be important. And so that points to the, perhaps, the reason why,
so few people are doing dedicated range of motion work, but it also
reminds me that all of the studies that were described at least in this review and some of the other ones that were not
really show impressive
changes in limb range of motion. I mean 20 plus percent or even 15 percent with PNF.
I mean these are big changes that are going to benefit us. They're going to offset the age-related losses
inflexibility for sure if one is dedicated about these practices.
And in many cases, they're going to increase limb range of motion in ways that are going
to allow us better performance in certain physical endeavors.
Certainly better balance.
Or we haven't really talked about balance and stability, but range of motion can impair
balance and stability in but range of motion can impair balance and stability in
some extreme circumstances.
But by and large, limb range of motion, lack of tightness, improved posture, improved physical
performance, excuse me.
And things of that sort is something that I think we can all benefit from and that are
key features of longevity.
We don't often think of them because we so prioritize cardiovascular health and the relationship
between the heart and brain health and resistance training and muscular skeletal hypertrophy or strength, etc. But as I delved
into this literature, it really highlighted for me the extent to which having really good limb
range of motion, at least maintaining limb range of motion as we age from year to year. And maybe even improving limb range of motion can
be immensely beneficial for reducing pain for, again, improving posture, improving our ability to
perform, to walk, et cetera. And indeed, there's a whole literature that relates our limb range of
motion to things like pain management of things related to headache and so on and so forth. So
limb range of motion is not just about
becoming a contortionist or being able to
complete the yoga class.
It really is about maintaining the integrity
and the health of the neuromuscular system,
the connective tissue, and the neuromuscular connective network
because those are indeed working as an ecosystem
and a network.
I'd like to just briefly touch on PNF stretching for a moment.
Again, this is a vast landscape with many parameters and different practitioners. A lot of competing opinions out there
to put it lightly. Nonetheless, I do want to emphasize that the PNF training leverages
those spindle mechanisms and GTO mechanisms that we talked about earlier. But I realized that in describing the quadricep contraction hamstring stretch, a little mini-experiment
that hopefully you did, that I didn't really highlight the role of the GTOs, the Golgi-Tendon
organs that much.
And I would like to just briefly do that for a moment.
The GTOs have multiple functions.
In fact, I think even though GTOs are in every medical textbook, every physiology textbook,
every first-year neuroscientist learns about them when learning about the neuromuscular junctions
and the mechanisms of interoception, et cetera, they are likely to have other functions as well.
And one of the reasons why PNF stretching does work, whether or not you're doing that by using a strap
to pull back a limb or whether or not you're actively
contracting your quadriceps to then release
and emphasize stretch range of motion
for your hamstrings and related muscle groups,
is that activation of those GTOs,
meaning putting loads and tension into that system, can inhibit
the spindles in the opposite antagonistic muscle groups.
So one of the reasons why flexing, or I should say contracting your quadriceps really intensely
for some period of time, allows your hamstrings to subsequently experience greater range of
motion. And again, it's not just the hamstrings, subsequently experience greater range of motion.
And again, it's not just the hamstrings, but the related connective tissue and neural
circuits, et cetera, is because, yes, it's quote unquote, relaxing the hamstrings and
the spindle, but there's also a direct relationship between activation of the GTOs in the quadricep and release of the spindles
in the hamstring and related muscles.
This has a name, it's called autogenic inhibition.
It's a fancy name for contraction of one muscle group providing a relaxation of the other muscle
group that's antagonistic to it.
And it relates back to this idea of interleaving sets in the gym.
So if you think back to that example,
now it should make sense as to why, for instance,
if you do, let's say, a set of bench presses or shoulder presses,
and then you do, let's say you get 10 repetitions
and you fail on the 11th, that muscle is very, very fatigued.
If you were to rest some period of time and then go back
and do another set,
well, during the rest, that muscle group has been relaxing.
It's obviously not contracting the same way it was
during the resistance set.
But by going and doing a pulling exercise
that involves the antagonistic muscle group,
so strongly contracting the back muscles
through a pull like a pull down or a chin up
or a row type exercise, you're
activating or near activating the GTO system in those pulling muscles in a way that provides
autogenic inhibition for the pushing muscles.
Now again, the physios out there are probably either screaming or banging their heads against
whatever sound system this happens to be arriving through
to them saying, wait, but in many cases the GTOs aren't activated enough to provide that autogenic
inhibition. That's true, but even the subthreshold activation of those intraspinal circuits, so the
place where the GTO circuit and the spindle circuit interact can provide an additional replenishment
of, say, the pushing muscles
while you're activating those pulling muscles.
And this is at least one, not the only, but at least one mechanisms by which interleaving
push and pull, push and pull for both strength and hypertrophy training, but also for range
emotion stretching type training can allow you to achieve better results in a shorter period of time.
And I raise this because I want to keep in mind the efficiency of any training program.
We just a moment ago established that doing, for example, three sets of 30-second static
holds can be very useful for the hamstrings with, let's just say, for sake of simplicity
and practicality, a minute's rest in between. But during that minute's rest, you can stretch the opposite antagonistic muscle group, such
as the quadriceps.
Or if you want to use PNF training, you could do loading of the quadriceps in between.
So there are a number of different ways in which you can start to interleave static stretching
with PNF stretching.
You can start to interleave even PNF type protocols
with resistance training, although that gets a bit more complicated. You can really start
to construct and build protocols that are ideal for you. What we will do is for an upcoming
neural network newsletter, so for those of you that aren't familiar, the Hubert-Mindlab
podcast has a so-called neural network newsletter. These are monthly newsletters where we put distilled points from
the podcast and oftentimes protocols in a downloadable PDF form. You can access it by giving
us your email. We don't share your email with anybody. If you want to see examples of
these, you can go to HubertmanLab.com and go to the menu and see newsletter. You don't
have to sign up for anything to see examples of what these are like. I'll provide a couple of different protocols, one that is pure static stretching,
one that involves PNF type stretching, and I'll also put down a protocol that
involves the antagonistic interleaved muscle training of the sort that I've
been describing a few times throughout this episode. And then you can try and
apply those either separately or maybe combine them in some
way that's useful for your goals. There are a couple of key elements that are essential
for building a safe and effective range of motion, increasing program that arrived to us
both through the peer review to research and admittedly from people that have been involved
in teaching and training range of motion for a very long period of time. Some of you may be familiar with the so-called Anderson method.
It's been around for a long time.
I actually have never met Anderson.
I don't, I should know this.
I don't even know if he's still alive.
I hope he's still alive.
But in any event, there are a lot of different features to the Anderson and other protocols.
But one of the aspects of the Anderson protocol that I think is highly relevant, in fact, I
know is relevant to the peer-reviewed research that we're going to talk about in a few moments is this notion of
pushing through pain and how active or how passive to be about static stretching. Now, this is
somewhat subjective, right? If you think about getting into a stretch, again, we'll just use the
hamstrings, for example. So you're either reaching for your toes while seated
or maybe you're using a strap and you're raising your foot
overhead while lying down or maybe you're doing a
toe touch type exercise.
How far should you reach?
Where is the end range of motion?
Should you bounce?
Should you not bounce?
We're gonna talk a little bit more about that in a moment.
But Anderson has an interesting idea and principle which has thread through a lot of his teachings
that I think are very much in keeping with the study that I'm about to describe next, where
he emphasizes to yes, to stretch to the end of the range of motion, but not to focus so much
on where that range of motion happens to be that day.
So for instance, not thinking, oh, I can always touch my toes, for instance.
And therefore, that's the starting place for my flexibility training today.
But rather, to take the entirety of your system into account each day and understand that,
okay, provided you're warmed up appropriately, that you're now going to stretch your hamstrings, for instance, and you're going to reach down for your toes, but that your range of motion might be adjusted that day by way of tension and stress, or by way of ambient temperature in the room, and to basically define the end range of motion as the place where you can feel the stretch in the relevant muscle groups. I think this is important because unlike resistance training
or cardiovascular training, where we can measure distance
traveled over time, in the case of cardiovascular training,
or how much weight is on the bar and count repetitions, et
cetera, with range of motion training, of course,
range of motion is the feature that we're interested in.
But there is likely to be a lot of variation from day to day based on a number of different internal and external factors.
And so the Anderson method is really about getting into static and other forms of stretching.
I think today we've mainly been focusing on static stretching and holding the end range
of motion, but really paying attention to the feel of the stretch and the muscles involved.
And there are parallels in resistance and cardiovascular training, too, I realize, right?
In the case of trying to build hypertrophy, or I should say improve hypertrophy muscle
size, oftentimes the best advice that one can give is to don't try to lift weights,
but rather to challenge muscles.
Now, of course, you need to provide adequate loads in order to get hypertrophy.
But when you're training purely for strength, it's about moving weights. When you're training purely for hypertrophy or mainly for hypertrophy,
it's really about challenging muscles using weights or other forms of resistance. And similarly,
and in keeping with this Anderson method, when trying to build limb range of motion, doing
static stretching at a place where it's difficult, but that you can experience the
stretch of the muscle, cognitively, consciously, being able to focus on the muscles and their
stretch is at least as useful as is evaluating the current range of motion you're able to
achieve.
So what does this mean?
This means feel the muscles as you stretch them.
Don't just go through the motions.
And this means don't get so attached to being able to always achieve, for instance, a stretch
of a given distance within a given session.
You might actually find that by just finding the place where you can't get much further
and holding the static stretch there, that on the second and third set that you happen
to be doing that day, that your range of motion will be increased considerably.
Maybe not, but very likely, yes, you will.
And of course, evaluating range of motion over time is the key parameter because that's
the goal of all this type of work.
Now along these lines, there is this variable that we've mentioned a few times of passive
versus active stretching.
And there's this even more nebulous variable, this even more kind
of subjective thing of how much effort to put into it. Should you push into the stretch?
Do you even want to bounce a tiny bit? Would you want to reach into that endpoint and try
and extend it within a given set and session? And for that reason, I was excited to find
this paper entitled, a comparison of two stretching modalities
on lower limb range of motion measurements
in recreational dancers.
It happens to be done in recreational dancers.
It's a six week intervention program
that compared low intensity stretching,
which they call micro stretching.
They used a capital M,
so I don't know if that means that it's proprietary,
although I didn't see evidence of conflict of interest,
but they call it microstretching,
but to be very clear, microstretching,
in the case of this manuscript,
is low intensity stretching,
and they compared that with
moderate intensity static stretching
on an active and passive ranges of motion.
Okay, so there are a lot of different variables are here,
but I'll just highlight a few things
that are really most relevant to us, and I'll give you the takeaway at the outset and then
return to it at the end so that if I lose any of your attention in the next couple of
minutes, at least you have that key takeaway.
Basically what they found was that a six week training program using very low intensity
stretching had a greater positive effect on lower limb range of motion than did moderate intensity static stretching.
I find that incredibly interesting. So very low intensity and we'll define what
that means in a moment. Here I'm quoting them. The most interesting aspect of the
study was the greater increase in active range of motion compared to passive
range of motion by the microstretching group.
This relates to what we were just talking about a few moments ago as it relates to the
Anderson method, which is that very low intensity stretching, meaning effort that feels not
painful, and in fact, it might even feel easy or at least not straining to exceed a given range of motion, turns out to not just be
as effective but more effective than moderate intensity stretching. So what is low intensity
static stretching? Well, they define this as the stretches were completed at an intensity
of 30 to 40% where 100% equals the point of pain, right? So 30% to 40% in these individuals,
and again, I'm paraphrasing,
induced a relaxed state within the individual
and the specific muscle,
and here they were holding these static stretches,
I should mention, for one minute, not 30 seconds.
Now, the control group was doing the exact same overall protocol,
so daily stretching for six weeks, the same
exercises, holding each set for 60 seconds, but we're using an intensity of stretch of
80% where again, 100 represents the point of pain, the point where the person would want
to stop stretching.
I find these data incredibly interesting for, I I think what ought to be obvious reasons.
If you're going to embark on a flexibility and stretching training program,
you don't need to push to the point of pain. In fact,
it seems that even just approaching the point of pain is going to be less effective than operating at this 30 to 40% of
intensity
prior to reaching
that pain threshold, the pain threshold being 100%.
Now, of course, this is pretty subjective,
but I think all of us should be able to register
within ourselves to whether a given range of motion
or extending a given range of motion
brings us to that threshold of pain or near pain.
And according to this study, at least,
operating or performing stretching at an intensity that's
quite low, that's very relaxing, turns out to be more beneficial in increasing range
emotion than is doing exercises aimed at increasing range emotion at a higher intensity.
Okay, so lower intensity stretching, I should say lower intensity static stretching appears
to be the most beneficial way to approach
stretching.
I think that's a relief, probably to many of us, because it also suggests that the injury
risk is going to be lower than if one were pushing into the pain zone, so to speak.
The author's offer, a number of different explanations as to why this approach, this
microstretching approach, might be more effective.
Here I'm paraphrasing from their discussion
where they mentioned that it could be hypothesized
that they had improved reciprocal inhibition
within the hamstring muscle group.
So this gets right back to the sorts of neural mechanisms
that we talked about before that somehow
by doing this low intensity stretching
that they were able to access some of those spindle
and GTO type mechanisms that we were referring to earlier
and the inhibition of hamstring and quadricep stretches.
They also offer a number of different ideas about how this could shift the activation
of the so-called sympathetic, remember the kind of stress division of our nervous system,
and to reduce that relative to activation of the parasympathetic arm of the nervous system.
I confess they have a couple of arguments around sympathetic parasympathetic that are somewhat
convoluted.
I will just, in fairness to the neuroscience on those systems, I wouldn't suggest putting
too much weight on their arguments about sympathetic and parasympathetic.
To my mind, they didn't really hold much water, but here I'm not trying to be disperaging
of the overall work, which I think is really quite sound,
which is that low intensity, so-called,
microstretching is going to be the most effective way
to increase limb range of movement over time.
I wanna just briefly return to this idea
whether or not to do ballistic or static stretching
before some sort of skill training or weight training or any kind of
sport or even cardiovascular exercise like running.
Again, the data are really split out there.
There are even folks who suggest that doing any kind of stretching prior to running is going
to lower running efficiency.
It's going to require essentially more work and more oxygen uptake at a given speed for
a variety of reasons.
And runners and that community argue about this endlessly. There are papers in both sides
and both directions. I'm sure I'll hear about some of this in the comments. I'm not really going
to take a stance on this as a consequence because the data are all over the place. However,
I think there's a general logic that we can apply in here. I'm borrowing from some conversations
and some information put out there by Dr. Andy Galpin, who I think is, of course, both an expert and
thinks about these things in a really sound and flexible way, no pun intended.
There are instances, for example, where an individual might want to do some static stretching
to increase limb range of motion prior to doing weight training, even if it's going to inhibit that person's ability to lift as much weight.
Why would you want to do that?
Well, for instance, if somebody has a tightness or a limitation in their neuromuscular connective
tissue system, some place in their body and system that prevents them from using proper
form, that they can overcome by doing some
static stretching.
Well, that would be a great idea, as Dr. Galpon points out.
Or for instance, if proper stability within the movement requires increasing limb range
of motion in some way, well, then compromising the use of greater loads could be greatly
offset by doing some static stretching to improve
say hamstring flexibility or another muscle group flexibility.
So we can't always think about just what's going to allow us or inhibit us from using the
maximal amount of weight or from running as far as we want to run as fast as we want to
run.
There are instances where people are trying to overcome injuries where they're trying
to come back from a reparative
surgery or something of that sort, coming back from a layoff where some additional static
stretching prior to cardiovascular weight training or skill training or sport of some
kind is going to be useful because it's going to put us in a position of greater safety
and confidence and performance overall, even if it's adjusting down our speed or the total amount of loads that we use.
So it's you that needs to consider whether or not for you and within a given training session, you want to do static training.
I should say static stretching range of motion training prior to or after that training session.
And similarly,
after that training session. And similarly, there are a lot of data points in the fact that doing some dynamic or even
ballistic stretching prior to skill training or cardiovascular weight training can be beneficial
in part to warm up.
The relevant neural circuits joins in connective tissue and muscles and as well to perhaps
improve range of motion or ability to perform those movements more accurately with
more stability and therefore with more confidence.
And while Dr. Andy Galpin would never name any protocol after himself, he's far too humble
to do that, I've named a couple of protocols after him, particularly the Galpin equation
for hydration because he was willing to stick his neck out there and put down some specific
numbers that people could follow in order to ensure proper hydration during training.
You can look up the Galpin equation elsewhere.
You can just Google it or look elsewhere, you'll find it.
Dr. Galpin has also been very thoughtful and generous and I think very accurate in offering
a kind of a general organizational logic for how to think about
the goals of a particular training session and thereby to decide whether or not you're
going to do ballistic or static stretching and so on and so forth. So we can refer to this
general approach as galpinian, galpinian. Is that right? Galpinian Ian, logic. Galpinian logic.
Thus far, we've been talking about stretching for sake of increasing lymphlexibility and
range of motion, but there are other reasons perhaps to embark on a stretching protocol.
That include both our ability to relax and access deep relaxation quickly, as well as even
to reduce inflammation and perhaps even combat
certain forms of cancer.
If that sounds really far-fetched, I want to emphasize that the study I'm about to share
with you in a moment was actually carried out by one of the directors of a division of
the National Institutes of Health.
This was the work of Helen Langavan, who is a medical doctor, has done really
important work on the mechanisms underlying things like acupuncture, and has approached
all that from a very mechanistic viewpoint, right?
So not looking just at the effects of acupuncture, but really trying to understand what sorts
of cytokines in flammatory molecules
and pathways are activated, what sorts of neural mechanisms get engaged by things like
acupuncture that impinges on the facial tissues and so forth.
And Dr. Languven is currently a director of the National Institutes of Complementary Health
and Medicine at the National Institutes of Health. So this is a major division supported by tax dollars that support systematic mechanistic
exploration of things like respiration, meditation, yoga, acupuncture.
So this is serious science applied to protocols and approaches that have been used for some
period of time, but really aimed at trying to understand what would the best protocols be
to evolve new protocols.
So there's a really interesting study done in animal models, but I think it's a powerful
enough result that I think we all should pay attention to it.
The title of this paper, and again, the last author is Dr. Langevin herself, is stretching
reduces tumor growth in a mouse breast cancer model.
And yes, you can get mice to stretch.
It turns out that,
if you gently lift up mice by their tail and they'll hold onto their cage, there's a
there's a way in which you can mechanically stretch them in a way that doesn't harm them.
First, I should mention that Dr. Langovan and others have shown that just a brief whole body
stretch of that sort induces an increase in activation of the parasympathetic
arm of the autonomic nervous system, again, not
arm-lim-arm, but the aspect of the autonomic nervous system that creates a whole body,
whole nervous system shift toward more relaxation. So, yes, indeed, stretching induces relaxation
at a systemic level, not just at a local level. And I think that's important,
probably not surprising to those of you that use stretching
regularly, but yes, it does indeed relax us.
Yes, you can do this in mice and see that in mice as well.
Here's what they did for this current study.
Oh, I should say this was a study published in 2018 in scientific reports.
They write recent studies have shown that gentle daily stretching for
10 minutes can reduce local connective tissue inflammation and fibrosis.
Now that's local tissue inflammation and fibrosis as well.
We now know as systemic inflammation and can induce relaxation systemically.
In this case, they focused on mice, not humans. Mites were randomized to a stretch versus no stretch condition and were treated for 10 minutes once a day for four weeks.
So it's 10 minutes of this passive whole body stretching a day for four weeks. What's remarkable, I mean, just I have to say is just striking is that tumor volume in these mice, they were able to induce tumors in these mice and the tumor volume at the endpoint was 52% smaller
in the stretch group compared to the no stretch group.
This is a highly significant effect and they point out in the absence of any other treatment
and they explored whether or not cytotoxic to immune responses were activated and a number
of other features.
They weren't able to get too deeply into the underlying mechanisms, but this is pretty
remarkable.
Even three weeks into this stretching protocol, this daily stretching protocol for these
mice, tumor volume was reduced.
I mean, bite, you know, it's almost halved.
This is pretty incredible.
So they have these measures of tumor volume and the only difference in the way these animals were treated and handled
was the introduction of this daily stretch. I find this result to be, of course, limited in the
extent that it's done in an animal model, not in humans. We have to point it out. But as they
point out in their discussion, our results demonstrate a 52% reduction in memory tumor growth
over one month in mice undergoing stretching for 10 minutes a day without any other form of therapy.
Do they think that stretching itself is changing the tumor size?
No.
In fact, they raised the possibility that stretching because of its impact on the fascia
might even create micro environments that are more permissive for tumor growth in certain
instances.
So they're careful to emphasize what I also believe to be the case, which is that it's unlikely that the stretching itself was directly acting to reduce tumor size, but
rather that there's this possible link between inflammation and immune exhaustion mechanisms that if you can periodically relax a nervous system here through stretching that it can affect certain pathways related
to the immune system that would allow the immune system to combat tumor growth to a significant
degree.
So, again, even though this is a study in mice, it argues that relaxation induced by stretching
can have a powerful influence on memory tumor growth.
Again, a huge effect carried out by one of the premier labs and individuals who do this sort of work
and think about this sort of thing.
And of course, I want to point out, it wasn't just Dr. Langavan that did this study.
There are a number of co-authors on the study.
We'll provide a link to the co-authors.
Excuse me, we'll provide a link to the study so that you can peruse it in more detail
if you like.
Now, as a related and somewhat final point, I'd like to return this to this idea
in this place, this real estate within our brain
that we call the Insular Cortex, the Insula.
As you recall, way back at the beginning of this episode,
we were talking about the Vaughan-Economo neurons
that Constantine Vaughan-Economo,
the Austrian scientists discovered.
And the fact that we are able to make and perform interpretations of our internal landscape
pain, our dedication to a practice.
For instance, whether or not we are in pain because it's a practice that we are doing intentionally
and want to improve ourselves or whether or not it's pain that's arriving through some
externally imposed demands or situations.
Well, the insula has handling all that.
And fortunately, there's a wonderful paper that was published as a few years ago now in
the journal Cerebral Cortex, which is a fine journal.
This is the year 2014 entitled Insular Cortex Mediates Increased Pain Tolerance in Yoga
Practitioners.
I'll tell you why I like this study.
I'm personally not a practitioner of yoga.
I've taken a few yoga classes over the years. I've done some of the hot yoga practitioners. I'll tell you why I like this study. I'm personally not a practitioner of yoga.
I've taken a few yoga classes over the years.
I've done some of the hot yoga classes.
Those rooms can get really, really warm, I confess.
And I've done the kind of standard yoga every now and again.
It's not something that I've kept up regularly.
This study explored the effects on brain structure volume
in yoga practitioners. And for those of you out there that are Fissi and Ados and yoga, they pulled subjects from having backgrounds
in the... Here, I'm probably going to mispronounce these different things and forgive me. The Vinyasa
yoga is the Ashtanga yoga is a younger yoga is theanda, yoga's okay. So some people were new to these practices,
some were experienced. The important takeaways were that they took these yoga practitioners,
and they didn't explore their brain structure in the context of yoga itself. They looked at
things like pain tolerance. So they used thermal stimulation. Basically, they put people into
conditions where they gave them very hot or very cold stimuli and compared those yoga practitioners of varying levels of yoga experience to those that had
no experience with yoga, so-called controls.
And they found some really interesting things, or a lot of data on this paper, but here's
something I'd like to highlight.
The pain tolerance of yoga practitioners was double or more to that of non-yoga practitioners,
even for those that weren't doing this
so-called hot yoga, right?
They also found that pain tolerance
was significantly greater both for heat pain
and for cold pain.
They also found significant increases in insular,
again, the insula of this brain region,
gray matter volume.
Typically, when we talk about gray matter,
we're talking about the so-called cell bodies,
the location in neurons where the genome is housed,
and where all the housekeeping stuff is there.
And then white matter volume tends to be the axons,
the wires, because they're in sheaths with this stuff
that appears white in MRIs and indeed is white under the microscope and indeed is white.
It's actually lipid, which is myelin.
So increased gray matter volume of the insula is a significant finding because what it
suggests is that people that are doing yoga have an increased volume of these areas of
the brain that are associated with intercept of awareness and for being able to make judgments
about pain and why one is experiencing pain, not just to lean away from pain, but to utilize
or leverage or even overcome pain.
So there are many studies of yoga and meditation out there, few that have as much mechanistic
detail as this one.
And in fact, there's a beautiful figure, figure three in this paper that shows that the gray matter volume of this particular brain region scales in a almost linear way with the
duration of yoga practice that somebody has been taking on in years.
So people that had, they had a few subjects that have up to 15 or 16 years of yoga practice
had much larger left insular gray matter volume, bigger brain areas associated with these abilities.
And I find this interesting because there are a lot of activities out there that don't
create these kind of changes in brain volume, especially within the insula.
So it appears that it's not just the performance of the yoga movements, but the overcoming or
the kind of pushing into the end ranges of motion and to push through
discomfort to some extent.
Of course, we want people doing that in a healthy, safe way, but that's allows yoga practitioners
to build up the structure and function of these brain areas that allow them to cope with
pain better than other individuals and to cope with other kinds of interoceptive challenges,
if you will, not just pain, if you will not just pain but cold
Not just pain but discomfort of being in a particular position to do that and again
We wouldn't want people placing themselves into a compromised position literally that would harm them
Especially given that earlier we heard that
Microstretching of the kind of non-painful sort low-intensity sort is actually going to be more effective for increasing end range of motion.
But this study really emphasizes the extent to which practitioners of yoga don't just learn movements.
They learn how to control their nervous system in ways that really reshapes their relationship to pain,
to flexibility, and to the kinds of things that the neuromuscular system was designed to do.
And as a final point, there's a beautiful graph in this paper, beautiful, I think, because it
explores some of the more subjective dimensions of yoga and insular function, which is a,
here I'll read it out in the nerdy form, and then I'll explain what it means. This is a frequency histogram of categories
of mental strategies used by yogis
versus controls during the cold pain tolerance task.
What they're describing here and showing is quantitatively
how people are conceptualizing cold pain
in order to get through it.
And the different categories are, for instance, distraction, right?
Some people just choose to distract themselves from pain or to attempt to. Other people will try
to ignore it. It's a lot like distraction, but nonetheless, to engage in a negative emotion,
sort of like, I'm going to dig, I'm going to be in resistance to this. Control subjects tended
to use those approaches. whereas practitioners of yoga tended
to use other sorts of subjective approaches, like positive imagery, to some extent, the
ability to relax despite the extreme cold. The ability to quote unquote, accept, like this
is just happening despite the extreme cold, to observe, to third person themselves.
And the greatest effect of course was to breathe, to focus on their respiration as a way to
deal with this challenge, this cold challenge.
Now all of that is subjective data.
But I want to remind you that the practitioners of yoga are not just using entirely different
mental strategies,
but they are far more effective at dealing with pain. Their pain tolerance is much higher
as evidenced by the other data in the previous graphs in the paper. So, while this podcast episode
is most certainly not about yoga per se, it's about flexibility and stretching. Flexibility and
stretching are elements within yogic practices.
And of course, yogic practices involve breathing and mental work and a lot of other things,
balance, et cetera. It's a vast landscape as many of you know. But I think that if ever there was
a manuscript that pointed to the utility of something like yoga for sake of tapping into a particular set of brain circuits and
mechanisms that could wick out into multiple dimensions of life.
So day-to-day life, stress, challenges in dealing with all sorts of external stressors, career-related,
family-related, uh, relationally, et cetera, et cetera, excuse me, but as well for increasing
range of motion for increasing
flexibility.
So if ever there was a practice that one could embark on that would not only increase
flexibility and limb range of motion, but would also allow one to cultivate some improved
mental functioning as it relates to pain tolerance and other features of stress management that
no doubt wick out into other areas of life.
It appears that yoga is a quite useful practice.
And so for those of you that are interested
in increasing limb range of motion,
and you're already a practitioner of yoga,
great, can imagine that someday there will be another study
like this one, and you'll be in that, you know,
10 or 15 to 16-year practitioner graph.
You'll be that dot way out on the far end of the graph that
shows that your insula is that much bigger than the rest of ours.
And therefore, your internal awareness and pain thresholds and stress management will
be that much better.
But of course, yoga isn't the only way to increase limb range of motion and flexibility.
Up until now, we've described a number of different ways to do that.
And we've arrived at some general themes and protocols.
Again, those themes and protocols will be distilled into some specific and precise lists
in our neural network newsletter.
But we can revisit a couple of them now just in summary and synthesis.
Static stretching appears to be at least among the more useful forms of stretching.
So low or zero momentum stretching, typically at useful forms of stretching. So low or zero-momentum stretching, typically
at end range of motion. I love this concept of microstretching, even though it's just
a couple of studies that have addressed whether or not high intensity or low intensity
static stretch holds are more beneficial. The idea, and indeed the data that low intensity,
so 30 to 40% of what one would consider painful appears to be more
effective than 80% of that threshold.
Find that incredibly interesting.
And then there's this idea of frequency.
It really does appear that getting at least five minutes per week total of stretching for
a given muscle group is important for creating meaningful lasting changes in limb range of motion.
And that is best achieved by five day a week or six day a week or even seven day a week
protocols, but those can be very short protocols limited to say three sets of 30 maybe in 45
or 60 seconds of static hold, although 30 seconds seems to be a key threshold there that can get you maximum benefit.
There is no need to do full 60 second holds unless you're doing fewer total sessions per week.
And of course, to always warm up or to arrive at the stretching session warm. And then, of course,
there are the other forms of stretching that we touched upon a bit, things like PNF. And we
talked about why PNF works, things like the spindle and
the gold g tendon organ reflexes that are built into all of us that we arrive in this world
with. And of course, the other forms of stretching that are known to be effective and important
such as dynamic and ballistic stretching. Again, stretching protocols that involve a
lot of momentum in order to improve range of motion for performance of particular types
of work that one is about to embark on.
Typically that would be physical work, but a whole interesting and unexplored landscape
is the extent to which changing limb range of motion and different types of body movement
actually shape our cognitive abilities.
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