A majority of us may think of exertional compartment syndrome in runners or possibly compressive garments.
Today’s blog is going to explore how our body – particularly the foot and lower leg – uses compartment pressure to efficiently transfer forces. After researching the concepts I am about to discuss with you, my approach to overuse injuries and my Podiatry practice as a whole has changed! It’s as if I look at injuries through a different lens.
Before we delve deeper into the concept of compartment pressure, we must first review a few key points which lay the foundation to impact and movement efficiency.
I decided to do it in a step-wise fashion to make it easier to understand.
Step 1 – Encounter Impact Forces
With every step we take our body encounters impact forces ranging from 1 – 1.5x our body weight (walking) to 3 – 4x our body weight (running)
These impact forces are designed to provide the kinetic energy to walk, run, dance etc.
Our body perceives these impact forces as vibrations – vibrations which are initially detected through the skin on the bottom of the foot. All vibrations (like a tuning fork) is set to different frequencies with walking impact forces being 15 – 20 Hz)
Step 3 – Damp / Load Impact Forces
As impact forces enter the body our soft tissue (muscles) respond to stop or damp the entering vibrations by contracting isometrically. The concept of loading through isometrics is a new concept so let me give you an analogy to better understand this.
If you imagine a tuning fork vibrating upon impact it will vibrate at a certain frequency. To stop the vibrating tuning fork one must either touch it or put it against something. Putting pressure against the tuning fork is analogous to the isometric contractions of our lower leg upon impact.
Step 4 – Elastic Energy Stored in Fascia / Tendons
As the muscles contract isometrically the fascia and tendon fibers slide thus allowing the joint range of motion needed for ankle dorsiflexion and STJ eversion. As the joints flex elastic energy is being stored in the fascia and tendons.
As we shift from late midstance to push-off the fascia and tendons release this stored energy swinging the leg forward into swing phase.
So where does compartment pressure come in? And what even is a compartment?
In our lower leg we have 4 compartments: anterior, lateral, superficial posterior and deep posterior. In our foot we have 9 compartments!
As our muscles contract (especially isometrically) compartment pressure and stiffness begins to increase. The degree of pressure or stiffness is dependent on the rate at which the muscle fibers contract as well as the number of fibers recruited.
How does this affect the loading response?
Well all compartments respond to vibrations of different frequencies. Walking impact force frequency is 15 – 20 Hz which is also the frequency at which the lower leg muscles contract.
The goal upon foot contact – regardless of the movement – is to match the stiffness in the compartments to that of the incoming impact forces. Any delay in creating stiffness or compartment pressure can result in an increased risk of injury.
I’ve begun to look at overuse injuries – particularly running injuries – with this concept and a clear association exists between delayed or inadequate compartment pressure on foot contact.
How can you begin to apply this concept to prevent impact injuries?
- Train the foot to detect impact forces faster and more accurately through barefoot training
- Condition the lower leg and foot to better create stiffness and compartment pressure through barefoot landing techniques
- Control training surfaces knowing that all surfaces vibrate differently with natural surfaces such as wood being the best
- Utilize compression sleeves to assist in damping vibrations
To learn more about impact forces and preventing injuries please visit www.ebfafitness.com and check out one of our Certifications