Exercise Selection and Adaptations for Athletic Speed Development

In traditional strength and conditioning, we use “strength training” as a blanket solution to cover up for our gap in understanding how the body was truly designed.

We use phrases of the like:

Strength improves neural intent

Strength increases sarcoplasmic and myofibrillar growth

Strength improves tissue quality and cross sectional area

Strength improves force development

Strength training improves our ability to “grind”

All of the above are true, but all of the above are relative to the needs and deficicines of the individual. Strength is a tool that is used to help an athlete or individual enhance their athletic qualities. Remember, health and performance are mutually exclusive. Unless your sport requires you to perform certain lifts for outcomes - your time might be best spent elsewhere.

To be truly fast, we need to have the core of our program based outside of the barbell lifts and properly training speed through maximal velocity acceleration and top end efforts.

So, before we can actually provide strength training regimens and programs,

How Do We DEFINE Strength as it Pertains to Sports Performance?

Getting strong is multifactorial. The weight room serves as GPP for any sport. Of course, certain strategies in the weightroom will elicit better performance in one’s respective sport.

The thing in the weight room, the biomechanical and neurological “transfer” is not very straightforward, and in many cases, the velocities at play in utilizing barbells are not even close to what is seen in sport. Why practice a movement that is 5-10 times slower than what you will actually do in sport, with an exaggerated, and often hyperextended, moment arm of the spine (axial barbell loading) and no factor of horizontal velocity, to enhance something dynamic like sprinting?

With that being said, we understand the force vector component may be missing, however, there are certainly MAJOR benefits to strength training that will help improve your speed and performance. Ultimately, strength as it pertains to sport is force potential.

Sprinters have greater muscle lengths in key movers. A longer muscle has a greater to shorten a high velocity than a short muscle. Training at length is the key for prime movers to be able to contract more efficiently in sprinting.

Traditional strength training can improve sarcomere length in untrained athletes but fails to do so in trained athletes. This increase in fascicle length in young athletes can be a contributing factor to rapid gains in performance along with improved muscle coordination, and neurological intent improvements.

A trained athlete will be able to display their force potential with greater technical abilities. Furthermore, where it can be misinterpreted as “not applicable” to sprinting this holds true if you don’t understand the reason. Basic exercises such as skips, marches, and the likes are all ways of developing coordination within the brain that help make harder cues and drills easier to understand. You wouldn’t have an athlete barbell free squat if they lack the technical ability to perform a bodyweight squat, a goblet squat, or squat to box.

Getting stronger happens on many levels in human physiology, and is not just expressed in one's ability to lift the most amount of weight from point A to point B. Being “strong” for athletic performance, in a truest sense, means that an athlete (or individual) is able to produce the right forces when needed in relation to their sporting skill.

This begs the palpable question, how strong is strong enough?

Although research and empirical experience have not clearly identified a range, we have some anecdotal evidence that has proved valuable.

The above image is based on the research of Suchomel et al 2016 & our integration of unilateral strength training with our athletes over the last year.

What we found: Athlete’s who can handle 1.25x their bodyweight in a unilateral low body lift have plenty of strength to make continuous improvements in their sprint and vertical times.

This was found across the board for over 250 individuals ranging from 16-22 years of age. Male or female. Every demographic of individuals needed different levels of strength. However, across all demographics, 1.5x bodyweight seemed to be the cut off point where no additional speed gains improved over the course of 13 weeks.

As we alluded to before, strength is specific. Strength is force. How an individual expresses force will determine how successful the force is used for athletic performance.

In order to successfully build force through exercise selection we must understand two fundamental principles.

Principle #1 The gait cycle

1. How we move through space and time.

Principle #2 Force vector training

1. How we direct force as power is plane specific.

The Gait Cycle

The gait cycle has three phases

Early stance heel strike

Mid stance

Late stance

During each phase of the gait cycle one is transitioning between external and internal rotation, inversion, and eversion, inhalation and exhalation.

During each phase of the gait cycle the body is using different muscles to achieve the task at hand based on the skeletal position of one’s structure.

We can align the muscles of gait cycle, sprinting and what’s happening in the weightroom to help mitigate stress and optimize performance.

Some of the Best Strength Exercises to Improve Speed

Broken Down by Each Phase of the Sprint

When you shift sprinting to the hierarchy of your programming for athletes it makes all subsequent work easier to program.

The kinematic locomotive movement of sprinting will tell you everything you need to know about selecting the right movements in the weightroom to help supplement your speed work. In order to do so, simply break down the movement from a biomechanical standpoint, identify the muscles working within that plane, and then create a template accordingly.

That said, it is my current belief that the hamstrings are the most important sprinting muscle in the air, whereas the gluteus maximus is the most important sprinting muscle on the ground.

Muscular strategy shift in human running: dependence of running speed on hip and ankle muscle performance

Tim W. Dorn, Anthony G. Schache, Marcus G. Pandy

https://jeb.biologists.org/content/215/11/1944

Changes in Muscle Activity With Increasing Running Speed

Heikki Kyröläinen 1, Janne Avela, Paavo V Komi

https://pubmed.ncbi.nlm.nih.gov/16194986/

Exercise Taxonomy of Performance

Vertical Plane Hip Extension

Horizontal Plane Hip Extension

Knee Flexion Training

Hip Flexion

Eccentric and Isometric Foot Strength

Eccentric Adductor Based Exercises

Alteration Based Exercises

Acceleration Phase of Sprinting (Horizontal Plane)

In early phases of sprinting, where the trajectory of one’s body represents greater knee flexion, toe off, ATP, and more glute utilization it would make sense to pick exercises that heavily involve these planes of movement.

Top Speed | Absolute Speed (Vertical Plane)

In later phases of sprinting in which you have more vertical stiffness, relative athletic posture, eccentric foot strike, fast wing leg recovery, cycling and casting - you should focus more on vertical triplanar competency such as posterior chain work, eccentric adductor work, eccentric/isometric foot work.

I hope this helps provide some clarity in your strength training. Comment below if you have any questions!

AM