SAJSM 477.indd


ORIGINAL RESEARCH

SAJSM  VOL. 25  NO. 4  2013   109

Objective. To determine whether a relationship exists between the functional movement analysis (FMA) score and lower-body injury rates 
in high-performance adolescent female football players.  
Method. Observations included a baseline FMA score and medical injury reports. Data were collected from 24 players’ injury and illness 
records over a 38-week training period. All football injuries requiring medical attention (including stiffness, strains, contusions and sprains) 
and/or the removal from a session, leading to training restriction, were included in the study. Off-season weeks were excluded. Pearson’s 
product-moment correlation coefficient was calculated to assess the strength of the linear relationship between the FMA score and the 
number of medical visits, and between the number of medical visits and the number of training-restriction days.
Results. There was no evidence of a relationship between the FMA score and injury risk in teenage female football players (r=0.016; 
p=0.940). A strong indication of a cyclical season in the training schedule was noticed over the 38-week study period. A substantive negative 
correlation (r=-0.911; p=0.032) was seen in the number of medical visits compared with the training-restriction days. Injuries during two 
peak periods could have resulted from overuse, increased training load, stress and overtraining.
Conclusion. It could not be shown that a high FMA score was associated with a lower risk of injury. The ultimate goal is thus to reduce 
recurrent injury in players with a high FMA count. The regular medical visits observed suggest that player condition is maintained by means 
of reducing injury and managing training-restriction days. Our findings are in accordance with previous studies in terms of the lower limb 
being the most frequent region of injury, specifically the knee. This study supports previous suggestions that it is essential to develop a 
prevention strategy to measure trauma and recovery. 

S Afr J SM 2013;25(4):109-113. DOI:10.7196/SAJSM.477

The relationship between functional movement analysis and lower-
body injury rates in adolescent female football players
D C Janse van Rensburg, MD; A Jansen van Rensburg, MSc; P C Zondi, MB ChB; S Hendricks, BA (Hons) Sport Science; 
C C Grant, PhD; L Fletcher, PhD

Section Sports Medicine, University of Pretoria, Pretoria, South Africa

Corresponding author: D C Janse van Rensburg (christa.jansevanrensburg@up.ac.za)

Football, one of the most popular team sports worldwide 
according to the Fédération Internationale de Football 
Association (FIFA) survey of 2006, is increasing in 
popularity, especially among young female players. [1] 
This high participation rate also associates football 

with a high injury risk, especially in teenage players. Numerous studies 
have found female players to be more prone to injury than their male 
counterparts.[2] This is especially true for youth players in competition, 
as they show a higher injury rate per match than their seniors.[3]

Although there have been epidemiological injury studies on 
female football in recent years, most of these focused on elite female 
players. [4] There are limited publications available on epidemiological 
injury records in adolescent female football players. In a 2001 - 2009 
study by Waldén et al.,[5] female football players showed a two-fold 
increase in injury incidents compared with their male counterparts in 
the same age group. Emery[6] and Söderman et al.,[7] performed two 
other studies on injury rates in female adolescent players, focusing 
on the 12 - 18- and 14 - 19-year age groups, respectively. However, 
these studies looked only at injury prevalence over 3[6] and 7 months,[7] 
respectively, which may not be sufficient to attain reliable injury 
incidents, taking all factors of a long season into account. Many of these 
injuries may have long-term consequences that include an extended 

phase of rehabilitation and inability to perform sports, as well as the 
possibility of incomplete recovery that could cause lasting disability for 
the injured player. Understanding and identifying injury risk factors are 
essential to developing and improving methods to prevent injuries. [8]

Compensatory and incorrect movement tactics are often used by 
players in an effort to achieve higher performance. These improper 
actions may emphasise poor body movement patterns during play, 
resulting in injury. In 2003, the FIFA Medical and Research Centre 
(F-MARC)[9] developed a structured training programme, ‘The 11’, 
aimed at amateur players aged 13 - 17 years and focused on core stability, 
lower-extremity strength, neuromuscular control and agility. The 
objective of this programme was to prevent or lessen injury  and thereby 
possibly enhance performance. A review of the original programme 
confirmed the potential to decrease injuries, but compelling evidence 
was not obtained due to poor compliance. Revisions to ‘The 11’ in 
2008, and later in 2010, improved the efficacy of the intervention, with 
research showing a 30% reduction in the risk for minor injuries, and as 
much as a 50% reduction in the risk for severe injuries such as anterior 
cruciate ligament (ACL) sprains.[10] As with standard warm-up exercises, 
this programme should be performed at least twice a week at the start 
of each training session. Another warm-up prevention programme 
that has been shown to reduce injuries significantly, specifically non-



110   SAJSM  VOL. 25  NO. 4  2013

contact ACL injuries, is the Prevent Injury, Enhance Performance (PEP) 
programme developed by the Santa Monica Orthopaedic and Sports 
Medicine Research Foundation. This programme has been shown 
to reduce ACL injuries by up to 60 - 89%. However, 6 - 8 weeks of 
consistency is required for these changes to be effective.[11]

Other intervention programmes have also been shown to reduce 
injury risks in athletes, if implemented appropriately. The Functional 
Movement Screen (FMS) is a validated and reliable screening tool 
consisting of seven different exercises that highlight any functional or 
biomechanical limitations during specific movement sequences.[8] The 
athlete is scored from 0 to 3 depending on how well the movement is 
executed, with 3 being the best. An athlete with a functional limitation 
or weakness will have a lower total FMS score and is at increased risk of 
injury when participating in sport. The FMS was designed by Cook et 
al.[12] to assess the balance of mobility and stability required to perform 
essential movements. The movements require specific neuromuscular 
co-ordination in a range of occupational and physical tasks. Use of the 
FMS score as a baseline for correcting movement in a rehabilitative 
setting could remove the primary injury risk factor in predicting 
performance durability or subsequent injuries.[13] These scores could 
be used during pre-season or baseline sports physicals to identify 
athletes with pain or movement limitations before the athletic season 
commences. Researched factors for injuries include poor mobility, 
stability, core strength and asymmetries.[8]

The functional movement analysis (FMA) programme is based 
on the FMS,[12] and is designed to evaluate the functional movement 
ability of an athlete off the field. Additional movements are included for 
further assessment of posture and pelvic stability. To differentiate from 
the FMS, the assessment scoring system has also been adapted from 
1 to 4 to allow a better reflection of the different competencies, and 
to monitor improvements of functional movement more effectively.

A training team of 24 adolescent female football players was the target 
group in this study. The group represented a high-performance squad 
recruited by national selectors at various tournaments throughout 
South Africa. The players were selected based on football skill and 
athletic potential. They were housed at a high-performance unit, where 
they received coaching and conditioning by national trainers and had 
unlimited access to sports science and medical interventions. 

The objective of this study was to examine the correlation between 
FMA score and lower-body injury rates in adolescent female football 
players aged 13 - 18 years over a 38-week training period.

Methods
Population
This was a descriptive pilot study based on the results of the high-
performance programme of the 2012 SAFA/LOTTO Basetsana Football 
Academy at the University of Pretoria in South Africa. Twenty-four 
adolescent female football players participated in the investigation. The 
players, aged 13 - 18 years, were assigned over a 38-week training period 
(January to September 2012). This period coincided with the athletes’ 
respective training and tournament season. It excluded the off-season 
period of October - December 2012.

Injuries and illnesses
Injury and illness surveillance included assessment by doctors and 
physiotherapists. Players had free access to the medical staff at all 

times. Attention was given to all football injuries requiring medical 
attention (including stiffness, strains, contusions and sprains) and/or 
the removal from a session, leading to training restriction. 

Procedures
At the start of the study, height, weight and body mass index (BMI) 
were determined. Observations included a baseline FMA score and 
medical injury reports. Participants qualified for inclusion in the study 
if they participated in regular physical activity at a competitive level. 
Participants were excluded if they used any orthotic device or joint aid 
(e.g. knee brace), or reported any recent (<6 weeks) musculoskeletal 
or head injury likely to have an impact on fitness performance on the 
FMA. Athletes received a zero score if pain was related to any part of 
the tests.

The FMA analysis is an adaptive version of the FMS as described 
by Cook et al.,[12] and entails ten movement assessments: posture, 
flexibility, shoulder mobility, one-legged squat, one-legged jump, 
overhead jump, lunge, rotational stability, trunk stability and bridging. 
The scoring system on the FMA assessment ranges from 1 to 4, with 4 
being the best possible score. The best total score that can be achieved 
on the FMA is 40. 

Intra-tester reliability has been shown to be most reliable when 
testing is performed by one person with a minimum of 6 months 
of experience in addition to clinical experience.[14] Therefore, in this 
study, only one tester was used, with 5 - 6 years of experience in the 
FMS testing procedure. 

Statistical analysis
The Pearson product-moment correlation coefficient, r – a measure 
of the linear association between two variables – was used to quantify 
the relationship between FMA and the total number of medical visits, 
as well as the relationship between the total number of medical visits 
and training-restriction days. The level of significance was set at the 
conventional p≤0.05. 

Results
During the 38-week study period, 24 players were evaluated (Table 1). 
The overall weight, height, age and BMI of the participants compared 
well with those of player groups used in similar reported studies. The 
FMA score rated average according to the FMA score card. During 
the 38-week study period, 15 of the 24 players reported a total of 38 
medical visits.

A high number of medical visits was not only observed in players 
with a low FMA score, but across a wide range of FMA scores (Fig. 1). 
Pearson’s correlational analysis confirmed a non-significant relationship 
(r=0.016; p=0.940) between FMA and the number of medical visits. Two 
distinctive peaks were evident in the number of medical visits during 
March and August: 13 and 9, respectively (Fig. 2). A slight increase and 
a definite drop in medical visits was evident in the months preceding 
and following the peak periods.

Fig. 3 depicts that the documented training-restriction days and 
the sum of medi cal visits peaked simultaneously during the months 
of March and August. The elevated training-restriction peak in March 
was evidently preceded by a slight increase in February and a gradual 
decline in April. Pearson’s correlational analysis confirmed a significant 
relationship (p=0.032; r=-0.911) between the reported number of 



SAJSM  VOL. 25  NO. 4  2013   111

medical visits and the number of training-
restriction days.

Training restriction was placed mainly on 
injuries in the knee, foot and ankle regions 
(Fig. 4). However, during the 38-week 
period, the knee followed by the lower leg, 

thigh, lower back and hip accounted for the 
highest incidence of injury. Although injuries 
were high in the lower leg, thigh, lower back 
and hip area, no training restrictions were 
documented. Injuries in these areas can 
therefore be considered less serious than in 

the foot and ankle regions, where training 
restrictions were recorded.

The mechanism of injury, in particular 
‘overuse’ and ‘forced extension’, peaked 
during the months of March, and ‘overuse’ 
peaked again in August (Fig. 5). Overuse 
was graded as a gradual-onset injury, while 
forced extension, fl exion and rotation, and 
blunt injury were categorised as acute-onset 
injuries.

Muscle stiff ness and strains accounted for 
16 injuries (28% each) and were the most 
frequent occurring specific injury types 
identifi ed. Other injury types were sprains 
(17%) and contusions (10%).

Discussion
Th ere was no signifi cant correlation between 
FMA score and injury risk in the players. 
However, a strong negative correlation 
(r=-0.911; p=0.032) was found between the 
number of medical visits and the training-
restriction days. A strong indication of a 
cyclical season in the training schedule was 
noticed during the 38-week period. Lower-
body injuries in these two peak periods 
could have resulted from overuse, increased 
training load, stress and overtraining.

In previous studies, a lower FMS score had 
a predictive ability and was a predisposing 
factor for injury in male participants in active 
military service,[15] as well as in male athletes 
in American Football.[8] The same is true 
for female athletes, although not necessarily 
female football athletes, with very few studies 
in this regard. [13] Further studies, such as this 
one, are warranted to determine FMS scores 
and injury prevalence among young female 
athletes. Previous research has confirmed 
that the screen ing of movement patterns 
can readily identify functional limitations 
and asymmetries, and can be used to lower 
injuries in high performers.[8] In the current 
study, the FMA as a score card was assessed 
relative to the number of recorded medical 
visits among the football players. However, 
the correlational analysis did not substantiate 
that a high FMA score would directly lead to 
fewer medical injuries.

Th e number of medical visits and training-
restriction days peaked during the months 
of March and August. Th is could indicate a 
cyclical season in the training schedule of 
the players, during which injuries could have 
resulted from overuse, increased training 
load, stress and overtraining. Th e training-

Table 1. Baseline physical characteristics of female participants (13 - 18 years) (N=24)
Age (years), mean (±SD)
Body weight (kg), mean (±SD) 
Height (cm), mean (±SD)
BMI (kg/m2), mean (±SD)
FMA score, mean (±SD)
Total medical visits, n
Players who reported medical visits, n
Total training restriction days, n
Study period (weeks)

15.7 (±1.3)
54.9 (±9.04)
164.0 (±5.95)
20.3 (±2.61)
29.5 (±2.9)
38
15
29
38

FMA  = functional movement analysis.

40

35

30

25

20

15

10

5

0

M
ed

ic
al

 v
is

its
 (N

=3
8)

 v
. F

M
A

 sc
or

e

Participants (age 13 - 18 years) (N=24), n

FMA Medical visits

1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24

Fig. 1. Number of medical visits in the 38-week study period v. total FMA score.

14

12

10

8

6

4

2

0

Ja
n

Months in 2012 (38 weeks) 

M
ed

ic
al

 v
is

it
s,

 n
 

(N
=

38
)

Fe
b

M
ar

A
p

r

M
ay Ju

n

Ju
l

A
u

g

Se
p

Fig. 2. Number of medical visits over the 38-week study period.



112   SAJSM  VOL. 25  NO. 4  2013

restriction peaks could also have been due to 
the fact that many of the players represented 
their respective U17 and U20 national teams 

during the same year. It has been shown that it 
is during competition where most incidences 
of injuries in female footballers occur.[3] Th e 

specifi c time-frame of this research coincided 
with the respective training and tournament 
seasons of the players, stretching over a 38-
week period. Baseline training and fitness 
occurred during January and February. More 
sport-specifi c skills training with increased 
load (i.e. quality and quantity specific) 
commenced in March, with mid-week and 
weekend matches in August. The study 
period excluded the off -season segment of 
3 months. The fact that a strong, negative 
correlation was found between the number 
of medical visits and training-restriction days 
further indicates that regular medical visits 
may maintain player condition in reducing 
injury and managing total restriction days. 

Injuries in football players have signifi cant 
implications, not only in relation to future 
participation in physical activity, but also 
in future morbidity and mortality related to 
physical inactivity. Th erefore, the reduction 
of injuries is critical. Injury prevention or a 
protective intervention training programme 
will help to lower football-related injuries. 
According to Emery et al.,[16] the risk of injury 
in youth indoor football players can be reduced 
by more than one-third with a football-specifi c 
neuromuscular training programme. Also 
with football being a team sport and players 
required to be at a high level of performance 
for the season, variation in training should 
be considered. Periodisation or fluctuation 
of high and low training loads (including 
changes in volume, intensity and strength 
training) within a small time-period, as well 
as balanced periods of rest and recovery, have 
proven to benefi t performance and reduce the 
risk of injury.[17]

In this study, the knee was the most injured 
region followed by the lower leg, thigh, lower 
back and hip. Th e lower leg, thigh, lower back 
and hip injuries were, however, less serious, 
since training restrictions were placed mainly 
on injuries of the knee, foot and ankle. Th e 
knee, foot and ankle regions can therefore 
be considered to be highly vulnerable areas 
of the football player’s body, which may also 
lead to lengthy exercise-restriction periods 
in the event of injury. This is consistent 
with other studies listing the most common 
injury locations in female football players 
as the knee, ankle and thigh.[18] Improved 
preparation and training, and a structured 
workout schedule with a specific area of 
focus, will ensure reduced training restraints 
of athletes.[19]

Months in 2012 (38 weeks) 

Medical visits Training-restriction days

Tr
ai

ni
ng

-r
es

tr
ic

ti
on

 d
ay

s 
v.

 m
ed

ic
al

 v
is

it
s

2

4

6

8

10

12

14

16

18

20

0

Ja
n

Fe
b

M
ar

A
pr

M
ay

Ju
n Ju
l

A
ug Se

p

Fig. 3. Number of medical visits v. training-restriction days over the 38-week study period.

Region count Training-restriction days25

20

15

10

5

0

Re
gi

on
 c

ou
nt

/t
ra

in
in

g-
 

re
st

ri
ct

io
n 

da
ys

Region of injury

H
am

st
rin

g

Q
ua

d

G
ro

in

A
nk

le

O
th

er

Lo
w

er
 le

g

Th
ig

h

Lo
w

er
 b

ac
k

H
ip

Kn
ee

Fo
ot

Fig. 4. Region of injury v. training-restriction days in the 38-week study period.

Months in 2012 (38 weeks)

7

6

5

4

3

2

1

0

M
ec

h
an

is
m

 o
f i

n
ju

ry

Overuse Forced extension Flex and rotation

Blunt injury Other

Ja
n

Fe
b

M
ar

A
p

r

M
ay

Ju
n Ju
l

A
u

g

Se
p

Fig. 5. Mechanism of injury over the 38-week study period.



SAJSM  VOL. 25  NO. 4  2013   113

The high rate of injury seen in a recurrent or increased pattern over 
specific months suggests the need for the implementation of a specific 
injury-prevention training approach. Soligard et al.[10] in 2008 indicated 
that players, in particular young female football players, could only 
benefit from proper biomechanical technique and improved awareness 
exercises to lower the risk of injury. Lerch et al.[20] is in agreement with 
this in his literature review demonstrating the effectiveness of injury-
prevention programmes in female youth football players. Due to the 
results of the mechanism of injury reported in this study showing 
overuse injuries as a peak, along with the suggestion of the cyclical 
seasoning in the training schedule of the players, it would be beneficial 
for the trainers to utilise different methods of quantifying training load 
– so as to provide a more quantitative measure of internal load on each 
player, to avoid overuse injuries and over-reaching.[21] While this will 
not affect performance,[22] it will allow for reliable internal load to be 
recorded and specific training prescription to be given accordingly,[23] 
which, in the long term, will assist in injury prevention and consequently 
player longevity.

Musculoskeletal injuries accounted for the majority of injuries in 
training. The most frequent occurring specific injury types were stiffness 
and strains. Although sprains and contusions occurred less frequently, 
these specific injury types can also be classified as acute-onset injuries. 
Thus, it seems that acute-onset injuries are a bigger concern than 
gradual-onset injuries. This varies, with previous research showing that 
young female footballers tended to sustain fewer strain injuries and an 
increased number of ligament injuries than their male counterparts of 
equivalent age.[24]

Conclusion 
It could not be shown that a high FMA score was associated with a 
lower risk of injury. The ultimate goal will thus be to reduce recurrent 
injury in players with a high FMA count. Our results agree with 
previous studies in terms of the most frequent region of injury being 
the lower limb, specifically the knee. Our study thus supports previous 
suggestions that it is essential to develop a prevention strategy to 
measure trauma and recovery. 

Trainers, coaches and medical staff may well consider monitoring 
the female football-training programme, the training load, the 
duration of training as well as the matches and the psychosocial 
recovery (monitoring the stress and strain) of each player. Due to the 
large variation between players, the individual variances over time 
are most substantial in relation to injury prevention. Trainers need, 
therefore, to gain information on an individual basis to identify when 
a player has an increased risk of injury. If necessary, the training 
schedule can be adapted or interventions used in which players are 
educated to manage injury in a better manner.

Areas of future study include quantitative recording of the training 
programme to correlate high peak injury occurrences with high 
peak training cycles. Recording and quantifying the internal load 
and recovery of players will allow future researchers to deduce more 
precise risk factors and trends for injury prevalence. While this study 
looked at the trends during a 38-week training period, it may be more 
reliable for future researchers to track similar trends over multiple 
seasons, allowing an intricate analysis into the cyclical training, 
season by season. Increased intra-tester reliability for FMS testing will 
strengthen future studies. 

Acknowledgements. Amy Bathgate is acknowledged for assistance 
with data collection.

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