Week 1 Notes - Training Principles PDF

Summary

These notes cover the principles of exercise training, including overload, specificity, reversibility, and individual needs. The document also details the general adaptation syndrome, progression, periodization, and detraining.

Full Transcript

Exercise Physiology 2
Training Principles

CRICOS 00111D
TOID 3069
Training Principles

CRICOS 00111D
TOID 3069
 Objectives
Define and discuss the overload, specificity,
reversibility (detraining) and individuality
principles of exercise training
Discuss the factors that affect the training
response
 Training Principles
The same for all sports
irrespective of intensity or
duration; same for
men/women Repeated
sprints?
objective of training is to
bring about physiological and
metabolic adaptations to
improve performance in
designated tasks
delay onset of fatigue
same for all forms of training
– strength
– endurance
– speed
– flexibility
– agility
 Training Principles cont.
Overload (frequency, duration, intensity)
– progression
– diminishing returns

Specificity - specific exercise elicits specific adaptations to imposed demands (SAID)

Individuality – all individuals do not respond similarly to a given training stimulus
– No one size fits all program
– Optimal training occurs when exercise programs focus on individual needs

Reversibility (detraining) – detraining rapidly occurs (7 days) when terminating a training
program; beneficial effects of prior training remain transient and reversible
– 1-2 wks of detraining reduces metabolic and exercise capacity

Training principles apply equally to all individuals and exercise groups
– athletes
– those recovering from injury (rehabilitation)
– sedentary individuals commencing exercise
– young, middle aged and elderly
– disabled persons & disease population groups
 General Adaptation
Syndrome
general adaptation syndrome applies equally to all forms of
training whether aerobic, anaerobic, or strength orientated
each form of training experiences the same pattern of
adaptation

Stages of the General Adaptation Syndrome

Stage 1 = athletes initial response to training (Shock or Alarm Phase)
– can last several days or weeks depending on load

Stage 2 = athlete adapts to exercise stress (Resistance Phase …often
called SUPERCOMPENSATION)
– increased level of normal function (neurological, biomechanical,
structural and mechanical)

Stage 3 = extended exposure to stress leads to exhaustion (Exhaustion
Phase)
– reduction in level of normal function due to fatigue, soreness, etc.
Stages of the GAS in response to training.
Note: Each physiological system responds differently to the
same stress.
1.Alarm 2. Resistance 3.Exhaustion
Reaction Phase (adaptation) Phase

Level of
Adaptation
Counter-
Shock

Shock Level of untrained performance

Fatigue Time
 Overload Principle
Regular application of exercise stresses greater
than normal bring about specific adaptations
that enhance physiologic function
Overcompensation
Compensation Involution
Stimulus

Pre-Exercise State

Fatigue

1 2 3 4
 Overload Principle
overload may be achieved by
manipulation of any combination of:
– frequency
– intensity
– duration/time
– (rest?)

in conjunction with exercise mode (type)

commonly referred to as the FITT
principle
FITT-VP
 Manipulating Overload
Frequency = represents the number of sessions per day, week, month
that exercise is prescribed
Intensity = represents the training stimulus (i.e. the load or work in a
certain time prescribed)
- generally, lower intensity but greater volume for health benefits whilst
higher intensity and lower volume for aerobic fitness

Duration/time = represents total exercise duration or number of times
(repetitions) a load is administered (also whether continuous vs
intermittent)
Rest= time interval between reps/ sets/ sessions
Frequency, load, exercise duration, # of reps and rest prescribed dependent
upon goals of the program, phase of training, age, fitness level etc
determines the physiological outcomes of training (Meir 2003)
 Progression
Progressive overload is required to bring about
continual stress requiring further system
adaptation
completion of the same exercise stimulus is ineffective
e.g. walking same duration, intensity and frequency per week

During all phases of exercise or training, overload
has to be increased gradually in a step like manner
– 5-10% limit (may vary with exercise or sport e.g. running vs. cycling)
– Depends on fitness
the training stress should be cyclic with periods
of overload followed by periods of recovery
- application of overcompensation cycle and
GAS
- periodization
- a step by step mesocycle
– 4 microcycles with fourth microcycle for unloading
 Periodization
Process of dividing the annual training plan into a series
of phases (mesocycles)

Training model concurrently decreases training volume
and increases training intensity as duration of program
progresses (inverse relationship)

Enables the manipulation of training intensity, volume,
duration, frequency, sets, reps, and rest periods

Assists with preventing overtraining

Provides workout variety
 Diminishing Returns

positive training adaptations cannot continue
indefinitely just by increasing volume and/or
intensity
e.g. running or chin-ups

Level of
Adaptatio
n

Time
 Diminishing Returns cont.
magnitude of improvement reduces as
adaptation takes place.
– rate and magnitude of improvement is
dependent upon the entry level of individual
– e.g. novice > elite athlete
– aerobic fitness improvements with endurance
training range between 5 and 25%
further increases in training load may not
result in continued improvements
– greater adaptation seen in the early parts of a
program than at the end
 diminishing returns with increasing training load
(Costill, 1986)

70
65
60
55
VO2 max

50
45 Athlete A
Athlete B
40
35
30
0 40 80 120 160 200 240
Training Distance (km/wk)
Specificity and reversibility

CRICOS 00111D
TOID 3069
 Specificity Principle
“Adaptations in the metabolic and physiological
systems depends on the type of overload imposed”
– specific overload of short duration induces
specific strength–power adaptations
– specific endurance training elicits specific aerobic
system adaptations

evidence to suggest that specificity may also apply to
testing at the same time that training stimulus
applied
– morning vs. afternoon training
– mimic competition environment
 Specificity Principle cont.

adaptation to training is observed more
specifically in those parts of the body that are
exposed to the training stress
– specificity of local changes
muscle changes (fibre type)
Movement ergonomics (cycling, running, team sports
energy systems utilized (specificity of VO2max)

SAID Principle:
“Specific adaptation to imposed demands”
 Specificity Principle cont.

the specific effects
of interval swimming
training on
swimming and
running
performance
minimal change in
running
performance
compared to
swimming
 Reversibility
the beneficial effects of training are transient and
reversible even in highly trained athletes
loss of physiological and performance adaptations are
termed detraining
reason why transition phases are not total rest periods
aerobic adaptations are more sensitive to inactivity than
strength (e.g. in oxidative enzymes involved in aerobic
metabolism, in blood volume and cardiac output)
most bodily systems can maintain their level of
adaptation with reduced load however, it appears that
maintaining intensity is the key rather than volume or
frequency
Detraining
Detraining
Detraining

Short Term (< 4 weeks):
4-14% ↓in VO2max
5-12%↓ blood volume (RBC and plasma
volume)
5-10%↑HR at submaximal workloads
↓endurance performance
↓ GLUT 4 and glycogen content
↑CHO metabolism during exercise
Detraining

Long Term (> 4 weeks):
6-20% ↓in VO2max
↓capillary density
↓mean fibre CSA (atrophy)
↓strength / power performance
 Detraining in strength
gains in strength may be seen after 1 to 2 weeks of training
limited information on strength decrements following
cessation of training
example: following 2 weeks of no training
12% reduction of eccentric strength
6% reduction of muscle fibre area
strength training more resistant to short periods of
inactivity
slower decay rate
physiological systems return to untrained state
reversal of hormonal and neuromuscular adaptations
training as few as 1 to 2 times per week may be adequate
to maintain strength training gains
key: training intensity with reduced frequency
 Detraining vs. Tapering
short-term reduction in training load prior to competition
– aim: “reduce the physiological and psychological stress of
daily training and optimize sports performance” (Mujika & Padilla
2000)
on entering the tapering stage, athletes should have reached
most or all of their expected physiological adaptations which
will become evident once the athlete has recovered from the
accumulated fatigue of prior training (Mujika & Padilla 2003)
taper of 1 to 3 wk reduces training volume by 40 to 60% while
maintaining training intensity; most efficient way to maximize
performance gains
from a physiologic perspective, 4 to 7 d provides time for
maximal muscle and liver glycogen replenishment, optimal
nutritional support and restoration, alleviation of residual
muscle soreness, and healing of minor injuries
 Changes found during
tapering
Physiological
↑ in muscular strength and power
improvements in neuromuscular function
improvements in hormonal function (e.g.
testosterone/cortisol ratio)
↑ in haematological parameters (e.g. hematocrit &
haemoglobin)
allows muscles to re-synthesize glycogen
repair training-induced damage

Psychological
↓ perception of effort
↓ perception of fatigue
↑ focus and drive (Mujika & Padilla 2003)
 Individuality Principle
individuals responses and
subsequent adaptations to
training vary greatly
– even if a homogenous group
– initial values – lower fitness
greater room for change

add to this the variability in
roles in a team and it is
evident why all players
should not train the same
or at the same intensity
– e.g. goal keeper vs. forward
in soccer
 Individuality Principle cont.
optimal training benefits come from programs
tailored to needs and capacities of individuals

programs should be designed with the
individual in mind and their...
– tolerance to training
– responsiveness
– recovery capacity
– individual training needs
type of sport, level of competition, weakness
– physical characteristics
– environmental tolerance
– “lifestyle”

(Meir 2003)