EXSC216 Principles of Training PDF

Summary

This document discusses principles of training, including progressive overload, specificity, variety, reversibility, recovery, and individualization for athletes. The material also touches on biomechanics of resistance training.

Full Transcript

EXSC216
Principles of Training
Part 1: Overview, Progressive Overload &
Specificity of Training
Principles of Training

Progressive overload
Specificity
Variety
Reversibility
Recovery
Individualisation
Principles of Training

Training Stimuli

Current Capacity
Supercompensation

Training Continuum

Recovery
Fatigue
Principles of Training
Progressive Overload

Adaptation requires exposure to unaccustomed stress

Training load (volume & intensity) must be progressively
increased
Detraining
Overreaching

Training loads required by elite athletes are very high

Untrained will improve very quickly with low stimulus
Accommodation

Adaptation to a constant stimulus
diminishes over time
Law of diminishing returns

Periodisation attempts to overcome this
General
Special
Specific

Approach for beginners & well trained
should be different
Specificity

SAID Principle – Specific Adaptations to Imposed Demands
Measuring Transfer

Transfer = gain in performance/gain in trained exercise

For example:
8 weeks of strength training
21% increase in 1RM squat
21% increase in vertical jump (100%)
2.3% increase in 40m sprint (10%)

McGuigan; in High Performance Training for Sports – Ch 1, p13
Specificity
Velocity Specificity

Coyle et al (1981)
Specificity – Bilateral v Unilateral

Many strength training exercises
are bilateral
Many sports require unilateral
movement

Unilateral training may be more
specific

Are there any benefits or limitations to
unilateral strength training?

Bilateral deficit
Specificity v Generality

Non-specific training can be important

Involve large muscle mass

Contribute to underlying strength/power development

Low training age participants do not require a highly specific stimulus

Periodised approach is very important

More general training with less experienced people

Always likely to require regular return to training aimed at enhancing general quality
Providing Variety

Exercise
Type
Speed
Volume
Intensity
Effect of different training

Cormie et al 2010
Reversibility

Cessation of training results in loss of training induced adaptation
Rate of decrease appears greater in well trained than untrained
Maximal strength relatively long lasting
4 weeks without strength training = 6-10% decrease in strength & 14-17% decrease in power
Preferential atrophy of Type II fibres
Reduction in neural drive

Periodization – Bompa & Haff 2009
Individualisation

Athletes require individualised programs
Genetic factors
Biological/Training age
Current capacity
Illness/injury

Responders & non-responders
Recovery
Training & Competition
Load

Performance
= Fitness/
Capacity
- Fatigue
Types of Recovery

Chronic program manipulation
Periodisation
Acute modalities
Hydrotherapies
Nutrition
Sleep
Compression garments
Massage
Stretching
Cryotherapy
 EXSC216
Principles of Training
Part 2: Reversibility, Individualisation &
Recovery
Effect of different training

Cormie et al 2010
Reversibility

Cessation of training results in loss of training induced adaptation
Rate of decrease appears greater in well trained than untrained
Maximal strength relatively long lasting
4 weeks without strength training = 6-10% decrease in strength & 14-17% decrease in power
Preferential atrophy of Type II fibres
Reduction in neural drive

Periodization – Bompa & Haff 2009
Individualisation

Athletes require individualised programs
Genetic factors
Biological/Training age
Current capacity
Illness/injury

Responders & non-responders
Recovery
Training & Competition
Load

Performance
= Fitness/
Capacity
- Fatigue
Types of Recovery

Chronic program manipulation
Periodisation
Acute modalities
Hydrotherapies
Nutrition
Sleep
Compression garments
Massage
Stretching
Cryotherapy
 EXSC216
Biomechanics of Resistance Training
Part 1: Levers
Biomechanics of Resistance Training

Levers & Mechanical Advantage

Force-velocity relationship
Eccentric contraction
Isometric contraction
Concentric contraction

Length-tension relationship
Levers
Fulcrum:
Moment arm
pivot(effort
Torque (moment): point arm,
of a lever.
degree lever arm,aresistance
to which force tends to
Lever:
arm):
rotatea rigid object
perpendicular
an object that
around
AKA Axis of Rotation is
distance
a used with
from
fulcrum a
the fulcrum
line of to
either
actionmultiply the mechanical
of the force to the fulcrum. force (effort) or
resistance force (load) applied to it
Resistance
Arm (MR) Effort
Resistance Force (FE)
Force
(FR) Effort arm (ME)

Fulcrum
Lever
Torque

Torque = Force x Distance

Force in Newtons

Distance in Metres

Therefore
Torque is Newton Metres or N.m1
Mechanical Advantage

Mechanical advantage: when the applied muscle force can be less
than the resistive force to produce an equal amount of torque

Mech Advantage = Effort arm/Resistance arm
Resistance
Arm (MR) Effort
Resistance Force
Force Effort arm (ME) (FE)
(FR)

Fulcrum Lever
Mechanical Advantage

A mechanical advantage greater than 1.0 allows the applied
muscle force to be less than the resistive force to produce an
equal amount of torque

In many cases, human movement is at a mechanical
disadvantage (i.e. < 1.0)

Are we generally suited to high force or high velocity
movements?
Levers

R
E F
First class lever F

E

Second class lever R R
F

E
Third class lever E R
F
1st Class Levers

Muscle force and resistive force act on
opposite sides of the fulcrum

Mechanical disadvantage in this
example

Baechle & Earle 2008
2nd Class Levers

2nd Class: muscle force and resistive
force act on same side of fulcrum with
the muscle force acting through a
moment arm longer that that through
which resistive force acts.

Baechle & Earle 2008 Fulcrum
3rd Class Levers

3rd Class: muscle force and resistive
force act on same side of fulcrum with
the muscle force acting through a
moment arm shorter that that through
which resistive force acts

Baechle & Earle 2008
Mechanical Advantage Changes

The muscle
moment relative to
the resistance
moment changes
during the action.

Resistance Arm length

Effort arm length

Baechle & Earle 2008
Mechanical Advantage Changes

Resistance Arm length

Effort arm length
Mechanical Advantage Changes

Resistance Arm length

Effort arm length
Mechanical Advantage Changes

Resistance Arm length

Effort arm length
MR = 50 cm
ME = 120 cm
ME ÷ MR = 2.4

MR
ME
 EXSC216
Biomechanics of Resistance Training
Part 2: Force, Velocity & Torque
Torque v Velocity

“B” has Greater moment arm = greater
torque

HOWEVER

Less rotation per unit of muscle
contraction = lower velocity

Majority of levers in human body are
3rd class
Suited to high speed of movement
Sacrifice torque production

A B
Force-Velocity Relationship

Force production capability of muscle declines
as velocity of contraction increases
Impact of Training

(a) (b)
FORCE FORCE

after

after

VELOCITY VELOCITY
Fibre Type & Shortening Velocity

Str & Cond –Biol Principles
Power

Power (watts) = Force x Velocity

Force = mass x acceleration
Velocity = distance/time
Force-Velocity-Power

Harris et al 2006
Force Dominated Power vs
Velocity Dominated Power
From the previous
equation……what are the two
aspects you could develop to
increase power?

If “power” is important in two
athletic performances or events is
it achieved in the same way?
Length-Tension Relationship

Optimal overlap of actin &
myosin filaments engages the
most crossbridges

Str & Cond –Biol Principles
Muscle Architecture

Baechle & Earle 2008
Muscle Architecture
Strength

Speed

Pennation angle = angle between muscle fibres and imaginary
line between muscle origin and insertion

Angle at resting length in mammals varies from 0° to 30°
Angle of Pull

Muscle force most efficiently converted to torque when angle of applied force is at
90° to long axis of the bone.

Angles other than perpendicular either cause bones to be:
Pulled together (stabilising force)
Pulled apart (dislocating force)
Strength Curves

Combination of length-tension relationship and angle of pull results in the
“strength curve” for a particular movement.

This can be termed a ‘strength curve’ and is different for different movements.

The most common is an “ascending curve” where force generating capacity
increases from the bottom to the top of the movement.
e.g. squat and bench press
Force generating capacity increases as you move from bottom
position to top (pos 4 to 1 in picture)
Factors Impacting Torque Curve
Shape & Amplitude
Muscle cross-sectional area (CSA)
Length of force & resistance arm
Angle of pull of muscle on bone
Muscle micro & macro architecture
Fibre type
Neural stimulus
Force-velocity relationship
Length-tension relationship
Providing Variety

Exercise
Type
Speed
Volume
Intensity