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This blog comes courtesy of a conversation I had with my good friend Mike. Its all about optimum range of a muscle. It kind of followed on from this piece of info…

The eccentrically-loaded muscle will start its contraction weak and then get stronger; the concentrically-loaded muscle will initiate strong, but get weaker as the contraction continues.

 I had never given this much thought before but this makes a lot of sense when we think of length tension relationships. A muscle will struggle to produce force when both too long and too short.  Being weak in both positions. Cross bridge attachment has an optimal range.  This will be true of both force production and conservation of energy. Too much cross bridge detachment will also cause a more thermodynamically expensive scenario as we split ATP and dissipate energy as heat.

Elastic energy will also I believe have an optimal range. Studies have shown that spring stiffness (ability to return energy) comes from optimal joint angles or ranges. Going beyond this range means that we dampen or absorb energy, again dissipating as heat through visceoelasticity of tissue. Different tissues have varying levels of stiffness and compliance, different ranges will bring into play these different characteristics as will our neurological intention (land or jump again) to move control stiffness through efferent spindle stiffness regulation.

If we look at the way we jump when we want to jump again, we can see that we use a shorter joint range than when we land for the final time.  When we finish we have a large bend of the knee to absorb ground reaction forces rather than reuse them. This has implications for our understanding of height, range and repetition programming for our training me thinks!!

Ecconcentric (both eccentric and concentric muscle contractions occurring in different planes) muscle action may also play a role in optimal cross bridge attachment. If a muscle was to lengthen in all three planes this may cause a scenario where we are going beyond the optimal range for the muscle in terms of force production and elastic energy recoil. By mitigating elongation of the tissue in a plane of motion through concentric shortening we may also keep an optimal range. It maybe this would happen in a more sub maximal scenario where energy return and energy conservation are more important than maximal force production. I feel that gait is a great example of this. Although maximal force production may also be mitigated by creating too much loading through joint range that is hard to transform.

This then got me thinking about how we train. Many times we are looking for maximal ranges in our training. Maybe we should be looking more at optimal ranges. This may have more implications for sports where we can control the range through skill however. Running is a great example. Controlling stride length will keep us within optimal joint ranges. We must also remember that optimal will be governed by the individual. This will be affected by tissue ability, limb length, speed ability and event. I expect it will be that different events within running e.g. 400 metres will need different joint ranges from a marathon as we balance need for all out power, power-endurance and endurance. Going beyond optimal means our ability to start the next phase of movement, either eccentric to concentric or vice versa, will be compromised. I think that deceleration and acceleration are part of running (unlike the pose method ideology!) However we can mitigate excessive amounts of both having to occur, increasing energy conservation.

If we look at a game of tennis it is much easier to hit a powerful shot when we can manoeuvre our bodies into position. When we are out of position our range of movement may have to be extended to reach the ball. The transformation from eccentric to concentric is sub optimal and affects the power of the shot. The tennis player many times at end range will hit a defensive shot back, aiming to get it in the court rather than a winner! Increases in amortisation from eccentric to concentric reduces cross bridge attachment also decreasing energy return. The closer we get to and stay at end range stretching for the ball the longer we have the amortisation phase reducing the energy gained in the loading motion.

This is a very theoretical piece and mainly my own thoughts (so blame me!!) but it may give us food for thought when we programme ranges/heights for our clients to move through when training.

More may not be better in all circumstances!!!

 

Today's blog has come about from a conversation I had with a friend of mine who is running the marathon. Like many runners when they get beyond then 10 mile mark he has been struck down by IT band pain.

After consulting the physio he was given some classic stretches for this. General hip ADuction off weight bearing etc. This got me thinking about the predominant view of muscle function and how if we length or strengthen a muscle then it will do this by default.

First of all the ITB and muscles that attach to it maybe individually fine, but when they interact with the foot in a functional position such as stride stance this may change.

A flat or high arched foot may cause excessive lengthening or a lack of lengthening of the IT band and associated muscles. However much we lengthen or strengthen these muscles in isolation, when placed in a functional chain they will be limited or affected by other sections of the chain e.g. the foot. This means that in isolation and decompressed from gravity these muscles will appreciate the stretch but this may make little difference to their ability when back in a functional position during such as during running.

Many times I have treated people who have foam rolled and performed all manner of stretches in an isolated way but to no avail. Once we have found a cause rather than a symptom they have become much better.

The real point here is just because we spend time lengthening or shortening a muscle it may not choose or be able to use the motion or strength we have given it in a functional scenario. It maybe that another part of the system will not allow it to or the muscle or group of muscles have to perform another role because another part of the body has not done its job.

Another example of this would be kyphosis. People send hours retracting the scapulae to 'strengthen' the muscles of the upper back but their postures never change. This maybe because something further down the chain such as the hips and ankles are not able to effectively flex and attenuate the ground reaction and gravitational forces. This means the upper back will have to lengthen to decelerate the spine flexing forward so that the neck and head can remain in a relative upright position. In this scenario would these muscles choose to lengthen and decelerate motion to create relative upper thoracic and cervical extension or, shorten and force the superior distal segments at the cervical to lengthen disrupting head/eye function. I believe the latter regardless of the 'strength' we have given them. One thing we cannot 'beat' or get away from is gravity and ground reaction (unless you have a spaceship of course!!!)

This maybe a reason why people with limited thoracic motion get an anterior head position. The inability of the spine to relatively extend means the neck muscles have to decelerate the forces and end up at lengthened and at end range.

Just some thought out loud really!!!!

Ben