Fitness Components and Human Physiology
Fitness Components and the energy systems
Each of the fitness components has a duration and intensity that can be linked to the energy systems that allow our body to complete the work. A high duration and low intensity activity will mainly use the aerobic energy system. A moderate intensity and moderate duration will use a mix of anaerobic glycolysis and the aerobic system. A short duration and high intensity activity will predominantly use the ATP-PC system.
(Note: If your understanding of the human energy systems needs a little refreshing then please refresh this by visiting the energy system folder which sits within the anatomy and physiology folder).
Each fitness component is plotted below against the energy systems which fuel it.
1 = Power, speed, max strength, agility
2 = Sub max strength
3 = Hypertrophy, anaerobic fitness
4 = Muscular endurance, aerobic fitness
You can see here that the fitness components of power, speed, agility and maximal strength (i.e. very high load, very low reps(s)) are all supplied primarily by the ATP-PC system (number 1 above). They are fundamentally done at close to 100% effort (meaning a rapid rate of ATP production is required). The ATP-PC system supplies ATP very quickly to fuel maximal or near maximal intensity exercise, but it also fatigues quickly which is why training for such components is short in duration.
Sub max strength and hypertrophy are supplied by a mix of the ATP-PC and Anaerobic Glycolytic systems with strength being more ATP-PC based (number 2 above) and hypertrophy being more anaerobic glycolysis based (number 3 above) - remember “feel the burn!”. Anaerobic fitness falls into the Anaerobic Glycolytic system (number 3 above).
Muscular endurance (to a degree) and aerobic fitness especially, fall into the aerobic system (number 4 above) although it’s important to remember that the anaerobic systems will make some contribution as the aerobic system ‘gears’ up to supply ATP. This is because for any activity ATP is needed immediately and the aerobic system takes time to start developing ATP. So while the aerobic system is ‘gearing up’ most activity will be supported by the anaerobic systems.
So, we are now left with the fitness components of balance/stability and flexibility to look a little more closely at. We’ll do that by discussing what all of the fitness components require of the nervous and musculoskeletal systems.
Fitness components and the musculoskeletal and nervous systems
When we use our bodies to do something we must have ATP for energy and the rate at which we need ATP dictates the energy system that will be used to supply the ATP. We also need to control our movement which happens through the nervous and musculoskeletal systems.
Each fitness component requires these systems to respond in a certain way in order for the exercise to occur. Some adaptations can therefore be expected in both the nervous and musculoskeletal systems as a result of training a particular fitness component.
The following table summarises some of the requirements placed upon these systems when training each of the fitness components listed. You will see that balance/stability and agility require programming of the reflexes related to the movement (i.e. are movement specific) as well as good awareness within the brain (i.e. a strong map of what ‘balanced’ feels like or what the ‘change in position’ should feel like) in terms of the map it carries of the movement and what it knows is important in terms of departures from that map.
You should also note that in almost all cases a nervous system that is primed up for the job ahead and a musculoskeletal system that is warm and pliable is a must.
(Note – to make sense of the following tables it may help you to review the nervous system, the musculoskeletal system and the adaptations to exercise folders that sit within the anatomy and physiology folder at ptdirect).
|
Nervous system |
Musculoskeletal system |
Speed |
We need to generate nerve signals at high rates to many muscles with very low delay times. The brain needs a well rehearsed motor pattern, priming of the pathways it will use, reflexes to control / correct the movement as it happens, and a nervous system without fatigue. In other words we will be fastest when we are doing something we are familiar with, have warmed up for, and when we are fresh. |
We need muscles that can contract quickly and take the shock (of foot strikes for instance) without tearing, connective tissue (tendons, ligaments) that can withstand rapid and repeated loading, joints that are well lubricated with synovial fluid and have good joint space, and bones that are strong and rigid in the lines of force we will repeatedly expose them to. |
Power |
We need to generate nerve signals at high rates to many muscles with very low delay times all at once. The brain needs a well rehearsed pattern with optimal sequencing of the movement to allow the most force to be generated quickly, have practiced firing all of the motor units it can at once, priming of the pathways it will use, reflexes to control / correct the movement as it happens, reflexes that don’t limit the muscle activity that can happen, and a nervous system without fatigue. In other words we will be most powerful when we are doing something we are familiar with, have warmed up for, when we are fresh, when we have done it enough before that the spinal reflexes don’t limit our contractions. |
We need muscles that can contract quickly and very forcefully without tearing, connective tissue (tendons, ligaments) that can withstand rapid and forceful loading, joints that are well lubricated with synovial fluid and have good joint space, bones that are strong and rigid in the lines of force we will expose them to. |
Flexibility |
We need the nerves to decrease their activity (frequency of firing to the muscles), a brain that does not perceive risk in the position (e.g. it’s familiar with the position and the joint(s) is healthy), spinal reflexes which have been conditioned to not fire in the range of motion we adopt, a generally relaxed nervous system in a low stimulus environment (think waterfall music and dark room) |
We need muscles and fascia (remember the coating around the muscle tissue) that isn’t damaged, torn, rigid. We need tendons and ligaments that are not damaged. We need the muscle and fascia to be warm as this enhances its pliability. We need to be stretching across a healthy joint where no injury is present (otherwise the muscles may be ‘bracing’ the joint in position to protect it). |
Balance/Stability |
We need the spinal reflexes to be finely tuned and responsive so that balance can be quickly restored, we need the brain to have been programmed on how to detect and correct changes in position of the body (including not over correcting). We need the nervous system to be alert (i.e. the pathways involved primed and ready). |
We need the muscles to be warm and previously fired to enable contractions to happen quickly. In cases where high loads may result we will need the muscles and connective tissues able to tolerate rapid and significant forces (e.g. if we were tackled in a game of rugby or football and put off balance as a result) |
Agility |
We need the brain to have been programmed how to create and execute changes in the position of the body quickly and efficiently. We will likely need to be able to fire many muscles at once to overcome momentum in one direction and shift it to another. We need the nervous system to be alert (i.e. the pathways involved primed).We need the spinal reflexes to be finely tuned and responsive so that slight modifications to position can be made rapidly (external forces such as the ground will mean the reflexes will have to quickly modify positions). |
We need the muscles to be warm and previously fired to enable contractions to happen quickly. High loads may occur with momentum changes so we will need the muscles and connective tissues able to tolerate rapid and significant forces (e.g. if we were going to side step someone in a rugby match). We need the bones to be strong in the lines of force that may eventuate. We need the joints to be healthy and well positioned/lubricated so rapid position changes can happen smoothly. |
Strength |
We need the brain to be familiar with the pattern we are using, have the reflexes to control the movement under high load (rapid nerve firing). We need the brain to know how to complete the movement safely firing the inner and outer units (deep and superficial muscles) effectively to both generate force and simultaneously protect the joints. We need spinal reflexes which can quickly adjust position to maintain alignment/balance under the load. We need to be able to grade the muscle contractions over the movement to allow control and make the movement smooth. We need to be able to access as much muscle as possible for the task. We need to have the nerve pathways primed and ready. We must know how to consciously control the movement when we get tired and need to be wary of technique changes. |
We need to have muscles that can shorten under high load without tearing. We need fascia, tendons and ligaments that can withstand the tension and maintain joint position under high load. We need bones that can cope with the forces we will exert through them. We need a healthy joint with good articulation, spacing and lubrication. We need all the muscles, connective tissue and joints to be warm. |
Hypertrophy |
The same as for strength with the caveat that even more so with hypertrophy we must be able and willing to focus during fatigue and consciously control unwanted movement (cheating). |
We need to have muscles that can shorten under moderate/high load without tearing. We need fascia, tendons and ligaments that can withstand the tension and maintain joint position when fatigued and under load. We need bones that can cope with the forces we will exert through them. We need a healthy joint with good articulation, spacing and lubrication. We need all the muscles, connective tissue and joints to be warm. |
Muscular endurance |
We need the brain to be familiar with the movement to aid in efficiency in terms of its use of the muscles. We need to be programmed to maintain a safe position when tired. We need spinal reflexes that are quick to correct balance. We need to be able to access a lot of different motor units over time to share the work around |
We need to have muscles that can operate when forces are low/moderate but fatigue is significant and lactate can be present. We need the muscles and connective tissue to be well conditioned to deal with the repetitive strains they will go through in a particular set of positions. We need the bones to be strong in the lines of force we will commonly endure. We need the joints to be healthy, well spaced and lubricated. |
Anaerobic fitness |
We need the brain to be as efficient as possible at the movements it is completing so that as little ATP is required as possible to complete the tasks. We need to have reflexes that aid this. We need to be able to maintain technique and relax when fatigued with lactate present and messages going back to the brain encouraging us to stop |
We need the tissues to be warm with good blood flow. We need the muscles and connective tissue to be strong so they don’t get damaged as we repeatedly load them especially during fatigue. We need the joints to be in good health. |
Aerobic fitness |
We need the brain to be as efficient as possible at the movements it is completing so that as little ATP is required as possible to complete the tasks. We need to have reflexes that aid this. We need to be able to maintain the cycle of movement when we are tired and running low on energy |
We need to have warm muscles with good blood flow. We need to have tendons that are strong and can withstand significant and very repetitive loading in a particular plane (think of foot strikes in marathon running). We need the bones to be strong in the lines of force we will repeatedly load them in. We need the joints to be in excellent health. We need the connective tissues to be without tears as these will get worse with repeated loading. |