The growing popularity of recreational running has resulted
in an increase in associated injuries to lower extremities (Latter, 1981) and
according to most reports 60% of these runners will experience injuries that
limit their activity levels (Brody, 1982). Statistics have revealed that injury
rate is higher in novice runners than their elite counter parts (Cook et al.
1990), this may be due to both biomechanical and physiological variables.
The impact period of the running stance phase is often
called the heel strike, most runners make ground contact with the lateral
aspect of the shoe sole at the heel. During the mid-support component, the foot
rolls into a pronated position with both forefoot and rearfoot in contact with
the ground. Control of this motion is affected by three muscle, tibialis
posterior, flexor digitorium longus and flexor hallucius longus. Upon
repetitive use, these muscle can become inflamed and produce conditions such as
shin splits (Clement et al. 1981). The final component of the stance phase
is the push off, when the shoe should
control the position of the foot with respect to the leg in order to maintain
stability (Nigg et al., 1987).
Over pronation is not desirable; various running injuries
have been reported to be associated with excessive foot pronation (Cook et al.,
1990). However, the combined movement of eversion, abduction and dorsiflexion
allows for surface adaptation and shock absorption and so is a necessary aspect
to running gait (Perry & Lafortune, 1995). Nevertheless over pronation
during the midstance phase results in a hyper flexible and unstable foot (Cheug
et al., 2006). ‘Motion control’ training shoes attempt to negate these effects,
either by realigning the foot or by a direct cushioning effect. Right leg foot
positions and rear foot angles.
In order for a shoe to resist excessive or unwanted motion
of the foot and ankle shoes can employ various characteristics such as a heel
flare, medial posting and dual high density cushioning materials. Each intended
to lessen the amount of rear foot movement experienced by an athlete. An
increased medial heel flare has been shown to decrease rear foot movement
(Clarke et al, 1983; Nigg & Morlock, 1987). Whilst a reduction in lateral heel
flare reduces ankle leverage, therefore reducing rear foot movement (Nigg and
Morlock, 1987).
The use of medial posting and dual high-density materials has also been found to reduce rear foot movement (Cheung & Nigg, 2007). Such motion control shoes have been shown to reduce rear foot angle by 4°. Although it has been found that pronation is of particular importance in the first 10% of stance (Duffey et al., 2000), as a reduction in rear foot movement at this time makes for a more rigid landing. Thereby increasing the impact shock to the lower extremity and contributing to overuse injury.
The use of medial posting and dual high-density materials has also been found to reduce rear foot movement (Cheung & Nigg, 2007). Such motion control shoes have been shown to reduce rear foot angle by 4°. Although it has been found that pronation is of particular importance in the first 10% of stance (Duffey et al., 2000), as a reduction in rear foot movement at this time makes for a more rigid landing. Thereby increasing the impact shock to the lower extremity and contributing to overuse injury.
Alternatively, it has been
suggested by Lieberman et al. (2010) that running shoes cause heel striking and
that barefoot running would make for a flat/forefoot strike. It was thought
that this forefoot strike would negate the impact peak of the heel strike that
was linked to injury and thus this style of running would not subject athletes
to the same types of impact loading. Ultimately, leading to the conclusion that
running shoes cause an impact shock and accommodate higher injury
susceptibility. Perhaps a key result of this study was the introduction of
minimalist training shoes such as Nike Free and Vibram Five Fingers, such
training shoes seek to emulate barefoot running since it was postulated that running
shoe cushioning and heel lift were not beneficial. However, both running
barefoot and with minimalist training shoes result in higher impact force
magnitude and loading rates compared to traditional shod running (Squadrone
& Gallozi, 2009). Both variables arguably possess a similar risk of injury
as impact shock, thus highlighting flaws in the ‘safe’ and ‘gentle’ natural of
running barefoot.
However, it has been shown that
the impact force acts as an external input to our system, allowing us to detect
the nature of the surface and adjust our muscle activation accordingly (Nigg +
Wakeling, 2001). Contradicting the notion that impact peak is associated with
injury (Zadpoort +Nikoofan, 2011) and instead providing a means for runners to
efficiently adapt to different terrains. As opposed to examining ground
reaction force data it has been suggested that the study of pressure variable
would be more appropriate. This would allow for the identification of the area
of the foot that first comes into contact with the ground, providing more
detail of what foot contact style is being adopted for different conditions
(Nunns et al., 2012).
Barefoot running is therefore not
the miracle practice frequently speculated in the media, making athletes more
efficient and injury free. Instead, it causes individuals to load the
associated joints in a different manner through an alteration in stride type,
the effects of which can be equally as injury inducing as traditional shod
running. The notion that barefoot running also results in greater running
economy can also be seen as a myth, although it rids the exerciser of the added
mass from trainers (which increase oxygen consumption by 1% per 100g), it does
not account for the need of greater proprioception. Overall leading to gait
alterations that would have already been of optimal measures.
Overall, literature evidence is
equivocal as to whether different footwear types truly can negate injury for
runners. Although variations in heel flare may reduce rearfoot movement it is
important to maintain a certain level of pronation (8-10°) for shock absorption and
terrain adaptation. This pronation is of
particular significance during the first 10% of stance and so should not be
eliminated. Whilst barefoot running/minimalist shoes have been shown to alter
stride types, distributing impact forces differently and not necessarily
preventing injury. It is important that coaches adopt a holistic assessment of
their athlete when screening for injury risk. Taking into account training and
physiological variables that may provide a clearer picture of injury, this may
include strength of the surrounding skeletal muscles and the variance of the
training programme.
