Energy and Exercise
Edited by Jamie (ScienceAid Editor), Taylor (ScienceAid Editor), Administrator
ATP and Energy
For muscles to contract they need energy. As you probably know, this comes from what we eat: more importantly, it comes from the glucose and triglycerides in the food. But the muscles do not directly get their energy from here. Their immediate source of energy is ATP (Adenosine TrioPhosphate) [pronounced - ah-den-o-zyn try-fos-fate] and it has the following structure:
As the diagram shows, there are a string of phosphates coming from the ribose unit which is where ATP gets its energy from. The last bond contains a lot of energy that is released when it's broken down and forms ADP (adenosine DiPhosphate). This is exactly the same as ATP but with one P removed.
To replenish energy reserves, the body uses energy from the respiration to put a P back onto ADP to reform ATP; and thus the molecule is recycled.
Aerobic and Anaerobic
Now that we are looking at this in more detail you must know that there are two types of respiration in humans: aerobic and anaerobic, but rather than being two separate types, they are part of the same pathway.
Anaerobic means without oxygen and the first stage of the reaction does not use any, anaerobic produces ATP. If the reaction continues it will use oxygen to produce even more ATP. However, if there is insufficient oxygen then only anaerobic respiration will take place and lactic (which is acidic) is produced as a by-product. The below table summarizes the two systems.
|Type of Supply||Near maximum for up to 1 minute||Long term exercise but lower intensity|
|ATP produced||2 per glucose molecule||Up to 36 can be produced per glucose molecule|
|By product||Lactate||Only carbon dioxide|
|Athletic Comparison||200m to 400m sprints||From 800m to marathons|
When not enough oxygen is getting to the muscles, the respiration will become more anaerobic. Continuing this will lead to a build up of lactic acid in the muscles. This will cause a pH drop in the blood plasma. This causes muscle fatigue where muscles ache and do not contract correctly because the pH levels interfere with the functioning of the proteins and enzymes. So this is what stops you when you are exercising too much.
All of this built-up of lactic acid does not stay in the blood indefinitely. It is taken to the liver where it is broken down to glycogen via the process of oxidation. This process in the liver however, requires oxygen. So after exercise we breath heavily to get enough oxygen to break down the excess lactate, this is known as an oxygen debt.
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Categories : Biochemistry
Recent edits by: Taylor (ScienceAid Editor), Jamie (ScienceAid Editor)