Research has shown that strength
training is effective for providing muscular and neural adaptations that can
prevent injuries, correct imbalances, and improve running economy in runners (Kawamoto
2010). As well as increased muscular
strength, neural adaptations include improved rate of force development (how
fast the muscle can generate force), improved stretch-shortening cycle
capability (use of free energy generated from the elastic properties of the
tendons), and motor unit recruitment and synchronization. All of these benefits
combined can help runners to sustain attacks, climb hills better, and finish
stronger in races (Yamamoto et al
2008).
The importance of increasing
force production can be demonstrated with Newtons 2nd law of motion
F
= m*a
F
= (force)
m
= (mass)
a
= (acceleration)
The
ability of a runner to accelerate their mass (body weight) is directly
dependent on the capability of the muscles to generate force. Since
acceleration is derived from velocity, a more relevant equation for sports
performance is the power equation:
P =
F*v
P
= (Power)
F
= (Force)
v
= (velocity)
Power
production, which is the product of force and velocity is one of the most
important factors for determining success in both brief and endurance events,
average power output is most often the main difference between winning and
losing. Thus the ability to increase force production which has a major
influence on power capacity and can be the key ingredient for improving athletic capability (Stone et al 2010).
Increases
in strength are accompanied by increases
in running economy, basically this means that the runner is now using less
energy over the same distance travelled in comparison to somebody with poorer
running economy (poor economy results in more energy expended). 5-7%
improvements in running economy are commonly reported in the literature
following participation in a strength training program (Stone et al 2010).
Strength Training Program
Design
Traditional
maximum strength training protocols are recommended for middle to long-
distance runners, involving lifting heavy weights (> 85% of 1 repetition
maximum) for low reps (1-5) with long interest rest periods (3-5 mins). The aim
of max strength training is to increase the weight to power ratio and maximize
force production which will result in faster and more powerful muscle
contractions that enhance power production (Kawamoto 2010).
As
a result of increased max strength, less effort is required for each stride. Time
to peak force in each stride is also decreased, this is very important as it
allows for a longer relaxation time during each stride (Storen et al 2007). It is during this
relaxation time that the delivery of Oxygen and Energy, and the removal of
waste products takes place in the muscles.
It
is recommended that bilateral exercises (e.g. Squat, Deadlift etc) be
programmed in order to recruit the higher threshold motor units and type 2 fast
twitch muscle fibres, and also unilateral exercises (e.g. Lunge, Step-Up etc) in
order to eliminate any imbalances (Storen et
al 2007).
Runners
should also perform upper body strength exercises in order to improve posture
and optimize gas exchange in the lungs. It is recommended to perform at least
two pulling exercises (e.g Pull-Up, Bent Over Row) for every pushing exercise
(e.g. Bench Press).
Injury Prevention
Running
injuries are common and studies show that upwards of 50% of runners get injured
every year (Fields et al 2010), furthermore
it has been shown that training errors such as excessive distance and sudden
changes to training routines are responsible for 60-70% of all running injuries
(Nielsen et al 2012). Typical running
gait favours certain muscle groups leading to the development of muscular imbalances,
typically runners’ hamstrings become dominant resulting in the gluteals becoming
weak and inhibited, this is known as gluteal amnesia. Corrective exercises
should be prescribed to promote normal muscle function. Muscle weakness, particularly
hip muscle weakness (hip flexors and abductors) has been identified as one of the
leading causes of lower extremity injuries.
The
three most common running related musculoskeletal injuries are medial tibial
stress syndrome (shin splints), plantar fasciitis, and Achilles tendinopathy.
All three are overuse injuries and can be prevented with simple corrective
exercises which should be performed alongside your regular strength program in
order to be proactive rather than reactive when it comes to injuries.
In
order to minimise your injury risk it is recommended to follow the ‘10% rule’,
this states that you should avoid increasing your weekly running volume by more
than 10% in any given week (Johnston et
al 2003).
Core
training plays a pivotal role not only in improving running economy but also in
reducing injury risk. Runners need to focus on stability when running, thus it
is the role of the core to limit any unwanted movement. You should think of the
core as anti-movement muscles and not as flexors as is commonly seen in most
gyms with people performing sit ups. The strength of your core is evident
especially during the latter stages of races when poor posture can lead to
decreased performance and wasted energy (Holland 2007).
There
you have just a brief snippet of the benefits of strength training for runners.
Get in touch and attend my Strength Training for Runners classes and lets put
all the research into practice and improve your athletic ability.
