What energy system is used by our body when carbohydrates is used without oxygen to produce energy?

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The aerobic energy system utilises fats, carbohydrate and sometimes proteins for re-synthesising ATP for energy use. 

The aerobic system produces far more ATP than either of the other energy systems but it produces the ATP much more slowly, therefore it cannot fuel intense exercise that demands the fast production of ATP. 

While the aerobic system doesn’t produce nearly as much power as the other systems, a major feature is its capacity which is virtually limitless, as it just keeps on producing ATP. 

Think of this capacity as the fuel tank of the diesel bus – it is so big that it’ll hardly ever run out of fuel. 

These stages involve more complex chemical reactions than the other energy systems which is why ATP production is much slower. (The more complex the process - the longer it takes to produce ATP)

The three stages which will be discussed in greater detail are:

1.      Aerobic glycolysis (slow glycolysis)

2.      Krebs cycle (also known as the citric acid cycle)

3.      Electron transport chain

Aerobic (slow) glycolysis – Stage 1

Aerobic glycolysis is exactly the same series of reactions as anaerobic (fast) glycolysis, except it just has a different outcome because sufficient oxygen is present. 

1. Initially stored glycogen is converted to glucose.  Glucose is then broken down by a series of enzymes.
2. 2 ATP are used to fuel glycolysis and 4 are created so the body gains 2 ATP to use for muscular contraction.
3. Pyruvate is created as the end product of the breakdown of glucose.  As oxygen is present pyruvate is converted into a substance called 'acetyl coenzyme A'.
4. Acetyl coenzyme A can then be synthesized in the second and third stages of the aerobic system to create more ATP.

The second and third stages of the aerobic energy system continue the breakdown of glucose that was started by aerobic glycolysis and result in the formation of the by-products carbon dioxide (CO2) and water (H2O), and the synthesis of more ATP. 

Mitochondria are known as aerobic ‘power plants’ as it is within these power plants that the majority of aerobic ATP is produced.

The second stage of the aerobic system also deals with the acetyl coenzyme A that is produced by aerobic glycolysis.  This second stage is known as the Krebs cycle.

Krebs cycle (Stage 2)

Fatty acids (from fats) and amino acids (from proteins) are converted to acetyl coenzyme A through a series of complex chemical reactions.  Along with the acetyl coenzyme A from glycolysis they enter the Krebs cycle and are broken down.  This results in ATP production and the by-products of carbon dioxide and hydrogen are produced.

Acidity in the muscle is what causes the anaerobic glycolytic system to fatigue. 

So in the aerobic system hydrogen combines with two enzymes and is then transported to the electron transport chain. 

The main purpose of the Krebs cycle is to generate hydrogen to transfer to the electron transport chain where it can be ‘dealt to’ in a way that will control acidity and enable the aerobic system to keep synthesising ATP.

Steps of the Krebs cycle:

1.  Acetyl-coenzyme A enters the Krebs cycle.
2.  Acetyl-Coenzyme A is broken down into carbon dioxide (a waste product which is expelled through breathing) and hydrogen.
3.  2 more ATP are synthesised during this process and made available to fuel further muscle contractions.
4.  Hydrogen is transferred to the electron transport chain. 

Electron transport chain (Stage 3)

The electron transport chain is the most complex and productive pathway of the aerobic energy system. 

It produces 34 molecules of ATP for every molecule of glucose that is used.  Its complexity however makes it very hard to understand – we don’t expect you to be an expert!

Once in the electron transport chain the hydrogen ions from the Krebs cycle undergo further chemical reactions.  Here they are combined with oxygen to form the end product of water.

The process of transferring hydrogen ions from its carrier molecules to oxygen and having the hydrogen ions move across a chemical gradient produces the energy required to combine ADP and Pi to form ATP.  In summary the electron transport chain works as follows:

Steps of the Electron transport chain:

 1.      Hydrogen ions from Krebs cycle are carried to the electron transport chain by carrier molecules.

 2.      Hydrogen ions are transferred to carrier molecules embedded in the electron transport chain where they go through a series of chemical reactions.

 3.      A hydrogen ion gradient is created.  As hydrogen ions move across this gradient another form of ATPase phosphorylates ADP (adds another phosphate group) to form ATP.

 4.      Water is created as a by-product as hydrogen combines with oxygen.

 In summary the ATP gained from the complete breakdown of 1 glucose molecule in the aerobic system is as follows:

            Glycolysis                                            2 ATP

            Krebs cycle                                         2 ATP

            Electron transport chain                     34 ATP

            Total                                                   38 ATP

From this we can see how the aerobic energy systems capacity to generate ATP is virtually limitless. 

Where the anaerobic glycolytic system synthesises only two ATPs from the breakdown of one glucose molecule, the aerobic system can synthesise 38 ATPs from one molecule, albeit very slowly in comparison.  This also explains how our capacity for low intensity endurance activities is so large.

Training the Aerobic Energy System

This energy system can be developed with various types of training.

• Interval training – Interval training for the long term aerobic energy system would have a work-rest ratio of 1:1 or 1:2.  The work periods would usually exceed several minutes and the rest periods would be active but at a lower intensity that could be sustained.
• Continuous training – Training that maintains a constant intensity and lasts for a prolonged period of time (usually longer than 15 minutes)
• ‘Fartlek’ training – A type of interval training whereby the exerciser varies the speed and effort throughout the training session according to how they feel ensuring that they can continue to exercise at all times (i.e. no rest intervals).

Examples of training that is primarily focused on the aerobic system are:

• Run of two minutes at mod/high intensity, followed by two minutes at low intensity (active recovery) repeated for 30 minutes.
• 30 minutes low/moderate intensity cycling, swimming or jogging without change in intensity.
• 30 minute jog over some hills requiring bursts of extra effort every now and then but never stopping throughout the jog.