D. Matthews and E. Fox, in their revolutionary
book, The physiological Basis of Physical
Education and Athletes, divided
the running requirements of various sports into the following “energy pathways”.
ATP-PC and LA, LA-O2, and O2
- ATP - Adenosine Triphosphate : a complex chemical compound formed with the energy released from food and stored in all cell, particularly muscles. Only from the energy released by the breakdown of this compound can the cells perform work. The breakdown of ATP produces energy and ADP.
Duration
|
Classification
|
Energy
Supplied By
|
1 to 4 seconds
|
Anaerobic
|
ATP (in muscles)
|
4 to 20 seconds
|
Anaerobic
|
ATP + PC
|
20 to 45 seconds
|
Anaerobic
|
ATP + PC + Muscle Glycogen
|
45 to 120 seconds
|
Anaerobic, Lactic
|
Muscle Glycogen
|
120 to 240 seconds
|
Aerobic + Anaerobic
|
Muscle Glycogen + Lactic Acid
|
240 to 600 seconds
|
Aerobic
|
Muscle Glycogen + Fitty Acids
|
The
result of muscle contraction produces ADP which when coupled with PC
regenerates ATP. PC is stored in the muscles. Actively contracting muscles
obtain ATP from glucose stored in the blood stream and the breakdown of
glycogen stored in the muscles. Exercise for longer periods of time requires
the complete oxidation of carbohydrates or free fatty acids in the
metochondria. The carbohydrate store will last approx. 90 minutes and the free
fatty store will last several days.
All
time energy systems contribute at the start of exercise but the contribution
depends upon the individual, the effort applied or on the rate at which energy
is used. The following graph depicts how the energy systems contribute to the
manufacture of ATP over time when exercising at 100% effort. The thresholds (T)
indicate the point at which the energy system is exhausted-training will
improve the rhresholds times.
Adenosine
Triphosphate (ATP) stores in the muscle last for approximately 2 secounds and
the resynthesis of ATP from Creatine/Phosphate (CP) will continue until CP
stores are depleted, approximately 4 to 5 seconds. This gives us around 5 to 7
seconds of ATP production.
To
develop this energy system, sessions of 4 to 7 seconds of high intensity work
at near peak velocity are required e.g.
3 X 10 X 30 meters with
recovery of 30 seconds/repetition and 5 minutes/set
15 X 60 meters with 60
seconds recovery
20 X 20 meters shuttle
runs with 45 seconds recovery
The Anaerobic Lactate (Glycolytic) System
Once
the CP stores are depleted the body resorts glucose for ATP. The breakdown of
glucose or glycogen in anaerobic conditions result in the production of lactate
and hydrogen ions. The accumulation of hydrogen ions is the limiting factor
causing fatigue in runs of 300 meters to 800 meters.
Sessions to develop this
energy system:
5 to 8 X 300 meters fast
– 45 seconds recovery – until pace significantly slows
150 meter intervals at
400 meter pace – 20 second recovery – until pace significantly slows.
8 X 300 meters – 3
minutes recovery (lactate recovery training)
There are three different
working units within this energy system: Speed Endurance, Special endurance 1
and Special Endurance 2. Each of these units can be developed at follows:
Speed Endurance
|
Special Endurance 1
|
Special Endurance 2
|
|
Intensity
|
95 to 100%
|
90 to 100%
|
90 to 100%
|
Distance
|
80 to 150
meters
|
150 to 300
meters
|
300 to 600
meters
|
No of
Repetitions/Set
|
2 to 5
|
1 to 5
|
1 to 4
|
No of Sets
|
2 to 3
|
1
|
1
|
Total
distance/session
|
300 to 1200
meters
|
300 to 1200
meters
|
300 to 1200
meters
|
Example
|
3 X
(60,80,100)
|
2 X 150m + 2
X 200m
|
3 X 500
meters
|
The Aerobic Energy System
The aerobic energy system
utilizes protein, fats and carbohydrate (glycogen) for resynthesising ATP. The
energy system can be developed with various intensity (tempo) runs. The types
of tempo runs are:
Continuous
Tempo – long slow runs at 50 to 70% of maximum heart rate. This places demands
on muscle and liver glycogen. The normal response by the system is to enhance
muscle and liver glycogen storage capacities and glycolytic activity associated
with these processes.
- Extensive Tempo – continuous runs at 60 to 80% of maximum heart rate. This places demands on the system to cope with lactate production. Running at this level assists the removal and turnover of lactate and body’s ability to tolerate greater levels of lactate.
- Intensive Tempo – Continuous runs at 80 to 90% of maximum heart rate. Lactate levels become high as these run border on speed endurance and special endurance. Intensive tempo training lays the base for the development of anaerobic energy system.
Session to develop this
energy system:
4 to 6 X 2 to 5 minutes
runs – 2 to 5 minutes recovery.
20 X 200m – 30 seconds
recovery
10 X400m – 60 to 90
seconds recovery
5 to 10 km
Energy System Recruitment
Although all energy
systems basically turn on at the same the recruitment of an alternative system
occurs when the current energy system is almost depleted. The following table
provides an approximation of the percentage contribution of the energy pathways
in certain sports. (Fox et al 1993).
Sport
|
ATP-PC and LA
|
LA O2
|
O2
|
Basketball
|
60
|
20
|
20
|
Fencing
|
90
|
10
|
|
Field Events
|
90
|
10
|
|
Golf Swing
|
95
|
5
|
|
Gymnastics
|
80
|
15
|
5
|
Hockey
|
50
|
20
|
30
|
Distance Running
|
10
|
20
|
70
|
Rowing
|
20
|
30
|
50
|
Skiing
|
33
|
33
|
33
|
Soccer
|
50
|
20
|
30
|
Sprints
|
90
|
10
|
|
Swimming
|
10
|
20
|
70
|
1.5km
|
70
|
20
|
10
|
Tennis
|
70
|
20
|
10
|
Volleyball
|
80
|
5
|
15
|
Table adapted from Fox E. L. et al, The Physiological Basis for Exercise
and Sport, 1993
ATP-PC System (Phosphagen System)/Anaerobic Alactic
The resynthesis of ATP
through ATP-PC system do not require the percence of oxygen (anaerobic). When
ATP is broken down during mascular contraction, it is continuously reformed
from ADP (adenosine diphosphate) and Pi (inorganic phosphate) by the energy
liberated during the breakdown of the stored PC (phosphocreatine)
ATP Lactic System/ Anaerobic Glycolysis
The ATP lactic system is
the second anaerobic pathway for the regeneration of ATP. Glucose and glucose
from glycogen is chemiccaly broken down into lactic acid by a series of
reactions. During the breakdown, energy is releases and through coupled
reactions, is used to resynthesise ATP. This process is called Anaerobic Glycolyisis.
ATP Aerobic System
The ATP Aerobic System
comprise of three main series namely the Aerobic Glycolysis, Kreb Cycles and
the Electron Transport System. Together these series release enough energy to
resynthesize ATP. This system is by far, yields the largest production of ATP.
Sports and Energy
Requirements
Sports can be categorized
along a continuum going from mostly aerobic (long distance), through a maxture
of aerobic and anaerobic (middle distance), and on to mostly anaerobic (short
sprint) activities.