Strength and Power.docx

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Strength and Power

***5.1: Non-muscular adaptations to strength training***

- Non muscular adaptations = neural adaptations. These occur between
the brain and the NMJ.

- Golgi Tendon Organs: refers to a proprioceptive sensory receptor
that detects changes in muscle tension, located at the
musculotendinous junctions of skeletal muscle

- Autogenic Inhibition: a reduction in excitability of a contracting
or stretched muscle, largely caused by the inhibitory input arising
from sensory receptors within the muscle. Literally means the muscle
generates its own inhibition.

- Reciprocal inhibition: the process whereby the antagonists of a
joint action relax to accommodate contraction of the agonists acting
on that joint

- Interneurons: creates neural circuits, enabling communication
between sensory or motor neurons and the CNS. Involved in reflexes,
neuronal oscillations and neurogenesis.

- Co-activation: when the brain fires both the agonists and the
antagonists during a movement cause it doesn\'t know how to
stabilise the joint. As we train, the nervous system adapts and
stops firing the antagonist muscles as it realises that it no longer
needs them during movements where they are not the primary movers.
As we train, reciprocal inhibition improves, reducing co activation.

- Our GTO\'s detect excessive force and apparently act as a protective
mechanism to stop the muscles generating more force than what they
can withstand. High force on the tendon generates a negative
feedback loop, inhibiting the muscle from generating more force =
more force the muscle tries to make, the more the GTO says nope. As
we strength train, the amount of inhibition to agonist diminishes,
allowing the muscle to activate more.

Reduced Recurrent inhibition from interneurons

- Interneurons have more of a contradictory role. The more we try to
activate, the more they try to get in your way. They try to help you
balance out the force by applying just enough but not too much.

- They are part of, but have a separate neural pathway, to the motor
nerve, this is called recurrent inhibition, meaning turning back so
as to reverse direction

- Interneurons also get less sensitive with strength training.

Increased Firing Frequency

1. A single pulse from the motor cortex of the brain, and down the
motor nerve to the muscle is called a "twitch" (a)

2. When another twitch is sent down the nerve and activates the muscle
before the previous twitch can relax (a+b), the pulses compound into
a "tetanus", increasing the force and the rate of force development
(c).

3. While tetanus is still not stable force, if so many twitches are
sent down that the force stabilises into what we think of as a
contraction, the contraction is said to be "fused (d).

- Slow twitch fibres tend to fuse with twitches as low as 10Hz, fast
twitch can fuse at 40 Hz.

- At a frequency over \~60 Hz (\~30 Hz in ST fibres), maximal tension
is produced, beyond which higher frequencies of stimulation have no
effect *on force*. However, at stimulation rates of \>60 Hz,
the *rate *of rise in force is greater. This is a characteristic of
high-power athletes who can hit firing frequencies of 120 Hz. The
faster firing frequency doesn\'t create more force, but generates it
faster. 

- The firing frequency of the nerve and the muscle that can accept it
is called "rate coding" and is particularly important to speed
training

Improved recruitment patterns (synchronisation) and improved activation
patterns

- If we start to shake when lifting heavy, this is a result of the
muscles trying to pull together and synchronise, in order to
generate enough force.

- Asynchronous contraction means that each MU fires at different
times, one is turning off whilst the other on and whilst it results
in less force it tends to be more smooth, but synchronous has them
going altogether, all at once but it can be a bit choppy.

- Both have pros and cons.

- there is a lot of timing that goes into the optimal application of
force, muscles turning on and off at optimal times. Improved
activation patterns from the motor cortex allow for improvements in
the timing of firing of agonists and synergists.

***5.2: muscular adaptations to strength training***

- Meaningful muscle growth requires challenge and stress.

- Training for specific outcomes alters the way your muscles adapt.

- During resistance training, both Type I and II muscle fibres are
recruited, presenting them with a potent stimulus for adaptation.
While both fibre types typically undergo an increase in
cross-sectional area, Type II fibres generally undergo greater
hypertrophy. But it is the pattern of neural stimulation that
dictates how fibre type adapts.

- Regular strength training involving activation of high-threshold
motor units will more easily recruit Type II fibres, and with
regular strength training these fibres transition from the basic
Type IIb fibres towards the more oxidative (enduring) form Type IIa
fibres. This increases the muscle\'s tolerance of this type of
loading allows for increased volumes of training. De-training
appears to reverse this transition, and transform Type IIa fibres
back towards Type IIb fibres

- In pennate muscles (those where the muscle fibres align on a
different angle to the tendon) which generally produce higher force
production than other types of muscle, the angle of pennation during
contraction can be increased with strength training. Such increases
in angle of pennation during contraction (towards the 'optimum
angle' of 45^o^) then allow for greater increases in muscle
cross-sectional area and the production of greater force.

- Lower pennation angles tend to be better for speed. So the hamstring
is not pennated at all, the fibres in direct line with the tendon
allowing for sprinting speed. The deltoids have many pennations,
making them much better at force

Hypertrophy

- Product of strength training.

- Not as essential to strength output as once thought.

- Hypertrophy is a result of the contractile elements in a muscle
getting larger and the muscle fibres themselves will then grow as a
by product of this.

- There is also an increase in the number of myofibrils within the
muscle fibre, aka proliferation.

- Some people will have more muscle fibres than others, but that is
the result of genetics, not hyperplasia. You can\'t even change your
basic fibre types much (i.e., Type I or Type II). While swapping
between IIa, IIb, IIx, etc. happens with training, you can\'t change
Type I into Type II, or visa versa. Great marathon runners, rugby
props, and sprinters are more so born that trained. 

Increase in the number of sarcomeres

- ST is an anabolic stimulus and triggers the body to promote protein
synthesis. This stimulus tips the balance in favour of synthesis
instead of breakdown.

- The increase in contractile proteins = increase in the number of
sarcomeres and note that these are typically added to the external
layers of the myofibril and in 'parallel', giving us that increase
in diameter, not length. So what we end up with is more
cross-bridges. Because each cross-bridge is capable of generating a
certain amount of tension, increasing the total number of
cross-bridges should lead to greater force production, so as a
result, hypertrophy usually gives us increases in strength.

Muscle Damage and Satellite Cells

- Remember the micro-trauma and inflammatory cytokine response
mentioned in the Ted-Ed video? Well this inflammatory cytokine
response awakens the muscle satellite cells which are usually
dormant. So, when you generate mechanical overload through strength
training and induce micro-trauma, these satellite cells respond.
Fuses to the cell to restore the integrity of the muscle fibre.

Muscle Tendons.

- Tendinous stiffness increases following high-intensity strength
training. This affects the time required to stretch the series of
elastic components within a muscle, and therefore affects the
recruitment rate and rate of force development to enhance the rapid
application of force.

***5.3: traditional methods of strength training***

- Traditional models are based on research done decades ago.

- The old-school model of resistance training for muscle strength uses
the traditional 3 sets of 12 repetitions at moderate-high loads,
slowly re-assessing the load over time in order to continue
progression. This model suggests that neural mechanisms play a role
initially followed by a larger contribution from muscle
hypertrophy. 

- Additionally, there may be some degree of independence between
hypertrophy gains and maximal strength gains instead of this
old-school progressive model of strength development. Instead it
appears that not only is there an imperative to intermix volume with
high-load strength training in order to maximise hypertrophy, but
there is also a need to be more responsive to the individual in
terms of load and volume adjustments at more regular intervals. In
more plain language, this means that 1. **hypertrophy requires
strength**, and 2. we shouldn\'t be using the method of \"keep
trying to do more reps at \'x\' weight until you can do 12, and then
increase the weight to the point where you can only do 8; keep doing
that new weight until you can do 12\...\" (i.e., adjustments need to
be much more frequent). 

- The information on Progression Models in Resistance Training for
Healthy Adults from one of the most prominent sources in the field,
the American College of Sports Medicine, suggests that **3 sets of 2
to 6 repetitions at approximately 85% 1RM or higher** is the
necessary stimulus for increasing muscle strength. In theory, this
ticks the boxes of \"multiple sets of low volume of high
intensity\". 

- This prescription is evidence-based and synthesised from a long
track record of studies employing basic exercise prescriptions. As
such, while it may still work, it could be considered quite
conservative, and is unlikely to be optimal due to what we know
about the need for variation, cyclical loading, and recovery in
order to optimise supercompensation.

- Additionally, this conservative or generic mould for strength
training may actually limit adaptation, specifically with regard to
sports performance. The further devoid from a sport-specific
strength application that a training modality becomes, the less
transferable any strength gains are. In a similar vein, if you want
to improve your 1RM squat, then squatting at your 1RM with very low
volume is going to be more effective than doing leg press at your
3RM despite the similarities in joint actions and muscular
recruitment.

***5.4: contemporary methods of strength training***

\*these models require 4-6 days of training and aren\'t practical for
S&C environments

5x5 Method

- High intensity

- 5RM or 87%1RM

- Only 3 training days per week with 1 day off between sessions. Big
lifts are split across 3 days.

- 5 reps, 5 sets though some exercises may only have 3 if they are
harder, ie: deadlift. Or could be a 3 x 3

Westside

- Derived from Russian and Eastern European weightlifting programs.

- 4 day split, 2 upper and 2 lower, a dynamic effort day and a max
effort day.

- Max effort: Trained with a large number of sets (8-12 sets) and
generally very few reps (1-2 reps) at near maximal intensity
(90-100% 1RM)

- Dynamic Effort: Similarly, trained with a large number of sets (9-12
sets) and generally very few reps (1-3 reps) at significantly lower
intensity often dictated by bar speed of 0.7 to 0.9 m/s (equivalent
to an implied load of approximately 50-60% 1RM). Note that when I
say \"lower intensity\" I mean lower %1RM, but every effort must be
explosive (as fast as possible) are are still maximal intensity in
that regard. Additionally, DE is often accompanied by additional
features such as external resistance to mimic the force curve (load
gets heavier towards peak concentric contraction) through the use of
chains or anchored power bands

- Another feature of this method is the variability of exercise
selection. Under what is known as a conjugate system, exercises are
regularly cycled (with some consideration of movement proficiency
and experience), so rather than always back squat as the lower body
exercise, an athlete may consider: Deadlifts, Front squats, Sumo
deadlifts, Box squats, Etc.

- Repetition method: after main lifts on both ME and DE days,
accessories are done with more conventional loads, ie: 2-4 sets,
6-10 reps. Every 4th week, ME days main movements are done deloaded
as a rep method day.

5/3/1 Method

- Uses the same fundamentals of weightlifting with an emphasis on
technique.

- Done starting with light loads and block progression or overload
model

- 4 sessions per week, each day focusing on one core lift.

- Uses elements of periodisation, increasing intensity in an inverse
relationship with volume and week 4 is a deload.

Stack 10

- Volume based method

- Has significant overlap with hypertrophy. Is used to help break a
plataeu.

- Is ramp protocol style but reps are capped at 10

- The general process to each exercise would be as follows for
whatever exercise you are completing:

a. Do a set of 10 reps with an empty (20 kg) bar.

b. Add 10% of your 1RM.

c. Do 1x10

d. Add 10% of your 1RM.

e. Repeat until failure.

- Generally this volume would be too excessive to be training multiple
lifts on different days, so it is perhaps best employed as a means
of overcoming plateaus in progression on a single lift at a time,
with other strength training sessions using more traditional maximal
strength loading (e.g. 3-6 sets of 1-3 repetitions per set).

***5.5: Hot topics in the literature***

Velocity Based training

- Based on the speed of the bar during the lift.

- Not looking at a fixed load

Reps in Reserve (RER) (Auto regulation)

- Auto-regulation involves you asking an athlete after the completion
of a set "How many more reps do you think you could have done?" The
response approximates what %1RM they are lifting

- The advantage of auto-regulation is that it allows you to account
for your athletes getting stronger between 1RM fitness tests, or to
have off days

***6.1: Force, Velocity and power***

Formulas:

- Power (J/sec or Watts) = Work/Time = (Force x displacement)/Time

- Displacement/Time = Velocity

- Power = Force x Velocity

When training power, the goal is to increase force output or velocity of
the task

Furthermore, when you are trying to decide just how fast the bar needs
to move when lifting, or the ideal loading to achieve peak power, there
is some indication that \~30% 1RM (range from 30-60% 1RM) will generally
achieve peak power (an ideal balance of velocity and force). But this
does not mean you cannot benefit from training other strength qualities.

Think back to the diagram for VBT. Heavy strength zones other than
\"absolute strength\" included \"accelerative strength\" and \"strength
speed\", while more speed-based properties include \"starting strength\"
and \"speed strength\".

That power PEAKS at \~30%. But remember that power is not either on or
off. Power is still being used no mater where in the force-velocity
curve you are. 

Load Power Profile

- Traditionally, we say power optimises somewhere between 30-60% 1RM,
but this is a pretty big range! Do not think just because you are
training with a power-optimising load that you are training power.
You must be lifting an optimal load ballistically. Cruising with an
optimal load is only lazy training.

- The goal of the load-power profile is to identify the optimal load
to train peak power.  LPP can also be used to identify athlete more
in need of strength or speed training. 

- Load-power profiling involves gradually loading a bar heavier and
heavier and getting them to do a ballistic movement with each load.
The required equipment is something that can measure velocity, such
as a GymAware (several thousand dollars) or force plate (many tens
of thousands of dollars). While a GymAware or force plate are
extremely accurate, they can be beyond the affordability of all but
universities, professional clubs, and sports institutes. More
affordable force/velocity assessment tools include Flex (infrared)
and VMaxPro (accelerometers) that come in at a few hundred dollars,
or Metric VBT (camera-based phone app) in the app store. Whilst the
accuracy may not be there, they are more cost friendly.

***6.2: Plyometrics***

- Plyos rely on the elasticity of our muscles, as well as the SCC, in
order to rapidly generate force.

- A plyo has a rapid strength at the beginning. The simplest example
(and first progression) of this would be to jump into the air and
stick the landing. On landing, the impact forces the muscles of the
legs to rapidly lengthen to absorb the force. This rapid lengthening
triggers the SSC to stabilise the landing.

- The next progression is to jump from the ground and land on the
ground but immediately jump again. This adds difficulty by adding an
explosive (concentric) movement to capitalise on the force and speed
generated by the SSC. Eg: hurdles, bounding etc.

- Further progressions would be something like a depth jump or a depth
jump into a counter movement jump

Plyo Phases

1. Eccentric: the lengthening or rapid stretch

2. Amortisation: isometric transition between the eccentric and
concentric.

3. Concentric: the shortening

Storage/use of elastic energy

- The plyometric effect is wasted (dissipates into heat) as coupling
time increases

- The plyometric effect is maximised when CON phase follows ECC phase
straight away

- The plyometric effect is contributes up to 70% of power from a
countermovement jump

- With training, more energy is stored and subsequently utilised as
muscle force increases

Stretch Reflex

- Muscle spindles detect magnitude and rate of length change; the
greater the impact, the greater the stretch and thus the greater the
\"spring\" (i.e., enhanced muscle contraction)

- The spindles not only trigger a \"spring\" from the agonists, but a
relaxation of antagonists. If you think back to the module on neural
adaptations to strength training, we\'ve already discussed the value
of reducing co-activation to improve force output. 

When it comes to programming plyometric exercises, the quantification of
load is a little different to other forms of power training. The optimal
volume is still somewhat unresolved, and sometimes measured differently
by different coaches.

The most common, and suggested metric for plyometric load is the number
of contacts per session. You can follow this general indicator for the
suggested contacts per session ranges:

- **Beginner** - 80 -100 per session

- **Intermediate** - 100 -120 per session

- **Advanced** - 120 -140\* per session

\* By the time an athlete is \"advanced\", training load management
becomes an important issue. Perhaps the athlete can handle 140 ground
contacts, but in the grander scheme of their training 140 will almost
certainly be too mu much. 

Despite the inherent benefits of plyometrics, concurrent strength
training in addition to SSC training is recommended. This means that
when planning a training week, it does not necessarily supersede other
resistance training for power development.

In terms of frequency, it will depend on the stage of your training
cycle as to how often plyometric sessions/components of sessions are
employed.

Training days in season and pre season will look different.

plyometric movements are useful for training to produce greater power
than concentric only movements, as more force is realised during the
concentric phase due to briefly stored elastic energy from a rapid
transition from the eccentric phase. As an additional benefit, training
may increase the elasticity of muscle & tendon complexes for the primary
joints used in plyometric movements.

***6.3: Traditional Gym Training for Power to Compliment Sport
Training***

Training heavy and slow

- Motor unit recruitment follows the size principle

- When you train heavy and slower, 1-5 rep range, you\'re working the
more high force, lower velocity portion of the force velocity curve.
This helps when performing movements from zero velocity that are
more explosive, o maximising motor unit recruitment from nil helps
with the efficiency of recruitment and rate of force development.
This also aids in overcoming the inertia imposed by body mass. Thus
the VBT term, \"accelerative strength\". 

- While \"velocity specificity\" is indeed a real thing (e.g. you may
have heard that, since heavy weights are moved slowly, training with
heavy weights will make you slow) be sure to keep your other
high-speed training and the pair of strength training + speed
training will make you faster. Getting stronger only makes you
slower if it\'s all that you do, but strength training + your
training on the field/track/court will make you faster.

- From a logistics point of view, you need to be able to exert high
force before being able to exert high force *quickly*. This is why
we see in \"block periodisation\" that we so a strength block before
power: strength plays an important part in power.

Training Explosively

- This has numerous approaches

- By focusing on the *intention *to move a load as quickly as
possible, there is evidence to suggest it enhances the neuromuscular
facilitation associated with power output, enhancing the rate of
motor unit recruitment and maximising muscular engagement. The
intention to move quickly may be independent of actual bar speed, so
my 90% 1RM back squat may be moving very slowly, but if my brain is
cuing to move like I\'m trying to jump, it may have similar benefits
to actual ballistic training.

- As mentioned previously, this relates to the size principle, but
also accelerated rate-coding (the speed of action potential
signalling), which allows for an increase in synchronicity (action
potentials reaching the motor unit at the same time). This can be
applied effectively with low-to-moderate loads of 30-60% 1RM, but
also with high loads \> 80%, as it is an internally driven mental
stimulus. Even if the load does not end up being lifted with
lightning quickness, as long as the ***intention ***to do so
remains, it can still be an effective contributory strategy to
improving power output. We call this \"maximal intent training\".

- Perhaps another of the most obvious approaches is to employ
weightlifting-style lifting. The weightlifting lifts are the Snatch,
and the Clean & Jerk. Usually, in the S&C environment, we don\'t
train full weightlifting movements, but only the more useful parts
of then for us (i.e. the weightlifting derivatives). Pulling a bar
from the floor has few sport specific applications, but exploding
from an athletic stance does, so rather than train to pull a clean
from the floor we may train to pull it from just above the knee (the
\"hang\"). Another weightlifting derivative, the \"power clean\",
essentially cuts out the full squat position after the catch phase.
So if we pull from the knee with a high catch we call it a \"hang
power clean\", which puts most of the emphasis on the explosive hip
drive from a sport-specific position.

- Generally, weightlifting derivatives (i.e. using parts of
weightlifting movements like \"hang power cleans\" or \"low snatch
pulls\") should use moderate-to-high loads for the optimal training
load. But technique is perhaps more important than the loading
parameters for weightlifting derivatives. Generally avoid training
sets of more than 3 snatches at a time or more than 5 cleans per
set; weightlifting can be exhausting work and fatigue during
weightlifting leads to lower power output and often a break-down in
technique. 

- Many S&C coaches believe that it takes at least 6 months for an
athlete to get sufficiently confident in the weightlifting skills to
overload them, so choose not coach them. This is not necessarily
true,

Some additional notes on weightlifting derivatives:

- Max extension at the hip, knee, and ankle is achieved during the
second pull.  This is known as triple extension.

- Triple extension is seen in a variety of athletic movements such as
jumping and running which is one reason why the snatch is an
excellent exercise for athletes to use in their weight lifting
program.

- Hips had the highest power demands and joint angular velocities.

- Plantar flexors contributed to 10% of the barbell's maximum
velocity.

- The knee bend in the transition phase allowed the body to use the
knee extensors' stretch reflexes to develop muscular power.

However, given the technique proficiency required for weightlifting
derivatives, it may not always be the most potent training stimulus.
Traditional weights and lighter loads are also effective for training
power. Completing common compound lifts (think Squats, Bench Press,
etc.) with loads in the range of 30-60% 1RM can be appropriate.

The major shortfall here is the inherent deceleration of weights towards
the end range of many of these movements. To overcome these deceleration
issues, accommodating resistance can be added (as was mentioned with the
Westside method in the week 5 content) using chains and anchored power
bands.

Alternatively, 'ballistic' movements can be used where the weight is
released at the top of the movement, creating a follow through and
minimising the deceleration under load.

Interestingly, depending on what type of exercise you employ, the
optimal loading is likely to change even if peak power is the ultimate
training objective across all exercises.

Take this example from Kawamori & Haff (2004) highlights the need to
manipulate load based on several factors including region of the body
being trained, multi- versus single-joint exercises and nature of the
exercise (weightlifting versus plyometric