SAJSM 377.indd


original research

SAJSM  vol. 25  No. 3  2013   81

Background. The abdominal musculature plays a protective role against lower-back injury. Knowledge of the asymmetry in abdominal 
wall thickness in healthy, injury-free cricket pace bowlers may provide a useful platform against which pathology could be assessed and 
the effects of training could be evaluated. 
Objective. To compare side-to-side differences in absolute muscle thickness and activity of the abdominal musculature and to compare 
these measurements at the start, with those at the end of a cricket season among a group of amateur pace bowlers. 
Methods. This was a controlled longitudinal prospective study. Rehabilitative ultrasound imaging was used to assess abdominal muscle 
thickness in 26 right-handed, injury-free cricket pace bowlers at the start and at the end of a cricket season. Thickness measurements were 
done at rest, during an abdominal drawing-in manoeuvre (ADIM) and the active straight-leg raise (ASLR) on the left (-L) and right (-R). 
Results. The absolute thickness of the non-dominant obliquus abdominis internus (OI) was higher than that of the dominant OI at the start 
(p=0.001; ES=0.87) as well as at the end of the cricket season (p=0.001; ES 1.09). At the start of the season, the percentage change during the 
ADIM, thus muscle activity, was higher for the non-dominant OI than for the dominant OI (p=0.02; ES=0.51). Absolute thickness of the 
dominant obliquus abdominis externus (OE) at rest was significantly higher at the end of the season compared with the start of the season 
(p=0.0001; ES=0.85). During ASLR-R, the activity of the left transversus abdominis (TA) was significantly higher than that of the right TA 
during ASLR-L (p=0.03) when measured at the end of the season. 
Conclusion. This study highlights the possible muscle adaptations in absolute muscle thickness and activity as a consequence of the 
asymmetrical bowling action.

S Afr J SM 2013;25(3):81-86. DOI:10.7196/SAJSM.377

Side-to-side asymmetry in absolute and relative muscle thickness 
of the lateral abdominal wall in cricket pace bowlers
B Olivier,1 PT, MSc; A V Stewart,1 PT, PhD; W Mckinon,2 PhD

1 School of Therapeutic Sciences, Department of Physiotherapy, Faculty of Health Sciences, University of the Witwatersrand, Johannesburg, South Africa
2 School of Physiology, Faculty of Health Sciences, University of the Witwatersrand, Johannesburg, South Africa

Corresponding author: B Olivier (benita.olivier@wits.ac.za)

Lower-back injury is one of the most common types 
of injury sustained by cricket pace bowlers.[1] The 
abdominal musculature plays a protective role against 
such injury by increasing the stability of the lumbar 
segmental vertebrae.[2] The assessment of thickness 

of the abdominal muscles including transversus abdominis (TA), 
obliquus abdominis internus (OI) and oblique abdominis externus 
(OE) is known to be a valid measure of size of the abdominal muscles, 
as well as a sensitive measure of change. Ferreira et al.[3] found that TA 
and OI percentage change in thickness are valid measures of activity 
compared with electromyography (EMG). Rehabilitative ultrasound 
imaging (RUSI) is often used as a surrogate measure for activation of 
the abdominal muscles. Muscle thickness, as measured by rehabilitative 
ultrasound imaging (RUSI), is well correlated with muscle thickness 
measurements derived from magnetic resonance imaging (MRI).[4]

Mannion et al.[5] and Springer et al.[6] conducted abdominal muscle 
activation studies in non-sporting populations and showed that there 
were no differences in activation between body sides. Rankin et al.[7] also 
found no statistically significant differences in muscle thickness between 
the left and right OI and OE when measured at rest, but a difference in 
TA was found where the left TA was thicker than the right in moderately 
active individuals. They did not specify whether the recreational activities 

were mainly symmetrical or asymmetrical. In contrast to the findings of 
the aforementioned authors,[5-7] Hides et al.[8] found that the OI on the 
non-dominant side of elite cricketers was thicker than on the dominant 
side. Hides et al.[8] assessed a small sample size of elite cricketers, including 
batsmen and bowlers. It was suggested that the asymmetrical demands 
of the repetitive bowling action may cause some muscles to be activated 
preferentially and hypertrophied above other muscles.[8]

Knowledge of the asymmetry in abdominal wall thickness in 
healthy and injury-free cricket pace bowlers may provide a useful 
platform against which aetiology of injury could be assessed and 
training could be gauged, and could provide a benchmark to direct 
RUSI biofeedback interventions in the future. 

The aim of this study was to compare side-to-side differences in 
absolute muscle thickness and muscle activation of the abdominal 
musculature, and to compare absolute muscle thickness and muscle 
activation measured at the start v. the end of a cricket season in a 
group of amateur fast, fast-medium and medium pace bowlers. 

Methods
Ethics
Ethical clearance was granted by the Human Research Ethics Comm-
ittee of the University of the Witwatersrand (reference M10430). All 



82   SAJSM  vol. 25  No. 3  2013

participants signed informed consent and had the right to withdraw 
from the study without suffering any repercussions. 

Participants
Twenty-six right-handed, premier league (amateur) cricket pace 
bowlers were invited to participate in the study on condition that they 
were free of injury. Participants were tested at the start and again at 
the end of an 8-month cricket season. 

Validity and reliability
The criterion-related validity of RUSI to measure muscle thickness 
has been established against MRI.[4] A strong linear relationship is also 
known to exist between abdominal muscle thickness change (TA and 
OI) and EMG amplitude during low levels of muscle contraction (up to 
30% of maximum voluntary contraction). No consistent relationship 
was found between OE thickness change and muscle contraction; 
therefore, this should not be used to detect muscle activity.[3] Intra-
rater reliability was established by Springer et al.[6] as being between 
0.93 (95% CI 0.86 - 0.96) and 0.99 (95% CI 0.98 - 1.00), as well as by 
Rankin et al.[7] as being 0.98 - 0.99 (95% CI 0.91 - 1.00).

Procedures
Abdominal muscle thickness was measured using a DP-6600 
digital ultrasonic imaging system (Shenzhen Mindray Bio-medical 
Electronics, China) with a 5 MHz curvilinear transducer with a large 
footprint (≥60 mm). The first author underwent training in the use 
of the equipment and performed all measurements. RUSI was done 
in brightness (B) mode. The ultrasound echo was recorded as a cross-
sectional gray-scale image.[9]

Each participant was positioned in supine with their legs straight. 
The transducer was placed along the lateral abdominal wall along 
the mid-axillary line, midway between the inferior angle of the rib 
cage (lower border of the 11th costal cartilage) and the iliac crest 
in the transverse plane.[9] The medial edge of the TA muscle was 
positioned at the medial edge of the ultrasound image.[9] This is the 
most appropriate position as all three muscles are well represented 
and relatively flat and easy to measure on the image.[7] All images 
were taken on the left and the right with the participant at rest at the 
end of relaxed expiration with the glottis open to avoid bracing. [9] 
The participants were then instructed to perform the abdominal 
drawing-in manoeuvre (ADIM) by exhaling and gently drawing 
their lower abdomen towards the spine,[10] using 20% of the maximal 
voluntary contraction. The following standardised instructions were 
given to each participant: ‘take a relaxed breath in and out, hold the 
breath out and then draw in your lower abdomen without moving 
your spine.’ Participants had the opportunity to practice the ADIM 
five times before measurements were taken. After performing the 
ADIM, the participants were instructed to relax their abdominal 
muscles completely. During the active straight-leg raise (ASLR), 
the bowler had to lift his leg 5 cm from the plinth.[9,11] ASLR was 
performed on the left (-L) and right (-R). The transducer position 
was kept constant during all of the above.[9] The research assistant 
verified proper execution of the ADIM and ASLR and recorded 
the frame number of each image. The thickness of TA, OI and OE 
was measured (in mm) on each of the following images: at rest, 
ADIM, ASLR-L and ASLR-R. The distance between the superior 
and inferior hyperechoic muscle fascias of the TA, OI and OE was 
measured in the centre of the muscle belly by using a vertical straight 

Table 1. Absolute thickness at rest and percentage change* in thickness in ADIM, ASLR-L and ASLR-R activity positions of the 
dominant v. non-dominant TA, OI and OE†

Pre-season (n=26) Post-season (n=26)
Non-
dominant 
mean (±SD)

Dominant 
mean (±SD) p-value

Effect size 
Cohen’s d

Non-
dominant 
mean (±SD)

Dominant 
mean (±SD) p-value

Effect size 
Cohen’s d

TA
Rest (mm) 4.6 (±1.4) 4.9 (±1.4) 0.25 0.17 4.9 (±1.4) 5.3 (±1.4) 0.10 0.35
ADIM % change 56.5 (±47.7) 41.9 (±31.2) 0.09 0.37 41.6 (±34.8) 27.0 (±27.1) 0.19 0.48
ASLR-L % change 17.4 (±34.2) 14.1 (±30.8) 0.66 0.10 15.8 (±25.6) 5.7 (±21.9) 0.16 0.44
ASLR-R % change 25.4 (±35.5) 16.5 (±26.3) 0.22 0.29 20.2 (±35.2) 5.5 (±20.8) 0.05 0.52

OI
Rest (mm) 14.2 (±4.1) 11.4 (±2.4) 0.00† 0.87 15.2 (±3.4) 11.9 (±2.7) 0.00† 1.09
ADIM % change 13.0 (±20.2) 2.7 (±21.6) 0.02† 0.51 11.1 (±15.5) 7.6 (±13.5) 0.37 0.24
ASLR-L % change 9.8 (±27.7) 1.5 (±20.1) 0.19 0.35 14.1 (±19.3) 7.7 (±21.5) 0.14 0.32
ASLR-R % change 8.6 (±21.4) 5.7 (±20.6) 0.58 0.14 4.0 (±24.0) 8.9 (±19.8) 0.40 0.23

OE
Rest (mm) 6.4 (±2.3) 6.0 (±1.4) 0.33 0.25 7.4 (±2.6) 7.5 (±2.1) 0.76 0.05

 
TA = transversus abdominis; OI = oblique abdominis internus; OE = oblique abdominis externus; ADIM = abdominal drawing-in manoeuvre; ASLR-L = active straight-leg raise (left);  
ASLR-R = active straight-leg raise (right); SD = standard deviation.

* Percentage change was calculated as a percentage of muscle thickness at rest: (muscle activated - muscle at rest) ÷ muscle at rest × 100.

† Significant difference between dominant and non-dominant sides (p<0.05).



SAJSM  vol. 25  No. 3  2013   83

line through the middle of the image. Measurements were conducted 
perpendicular to the muscle fascia. [10,11] 

Data analysis
Statistical analysis was conducted using Statistica (version 10). Thickness 
was reported as absolute muscle thickness at rest (TA, OI and OE) and 
thickness percentage change or muscle activity (TA and OI). Thickness 
percentage change was calculated as muscle thickness during activity 
as a ratio to muscle thickness at rest: muscle thickness in contracted 
state minus muscle thickness at rest, divided by muscle thickness at rest 
multiplied by 100.[10,11] Absolute thickness as well as thickness change 
on the dominant and non-dominant sides were compared using the 
paired Student’s t-test. Likewise, the absolute thickness and thickness 
change recorded at the start of the cricket season were compared to 
thickness measurements at the end of the cricket season using the 
paired Student’s t-test.[7] Statistical significance was set at p<0.05. Effect 
sizes were calculated using Cohen’s d where effect sizes of 0.2, 0.5 and 
0.8 were interpreted as small, medium and large, respectively.

Results
Twenty-six healthy, male, right-handed, fast, fast-medium and 
medium pace bowlers aged 18 - 26 years participated in the study 
(mean age 21.8 years, standard deviation (SD) ±1.8). Most had more 
than 6 years’ experience as a pace bowler, with the exception of two 
who each had 5 years’ experience.

The absolute thickness of the non-dominant OI at rest was higher 
than that of the dominant OI (Table 1), with large effect sizes found for 
pre- (ES=0.87) and post-season (ES=1.09) measurements (p=0.001). 
No side-to-side difference was found in absolute muscle thickness at 

rest for TA (p=0.25 and p=0.10) and OE (p=0.33 and p=0.76) at the 
start or end of the season, respectively. At the start of the season the 
percentage change during the ADIM, thus muscle activity, was higher 
for the non-dominant OI than for the dominant OI (p=0.02; ES=0.51). 
This was not the case when looking at post-season OI activation 
during ADIM (p=0.37).

Absolute thickness of the dominant OE at rest was significantly 
higher at the end of the season compared with at the start of the season 
(p=0.001; ES=0.85), while no difference was found in TA (p=0.07) 
and OI (p=0.28) thickness (Table 2). Furthermore, no difference was 
found in recruitment of the dominant and non-dominant TA and OI 
in ADIM (p=0.07 - 0.75), ASLR-L (p=0.07 - 0.88) and ASLR-R (p=0.06 
- 0.67) activity positions at the start compared with the end of the 
cricket season.

During ASLR-R, the activity of the left TA was significantly higher 
than that of the right TA during ASLR-L (p=0.03) at the end of the 
season (Fig. 1c). The same was true for TA during the ASLR-L (p=0.17) 
at the start of the season (Fig. 1a). During ipsilateral muscle activity in 
ASLR-L and ASLR-R, the activation of the left TA was higher than that 
of the right TA (pre-season: p=0.79; post-season: p=0.15).

Discussion
We investigated the absolute thickness of TA, OI and OE at rest as well 
as TA and OI activity in ADIM, ASLR-L and ASLR-R activity at the start 
and end of a cricket season. In our study, OI was the thickest muscle and 
TA the thinnest, which is similar to the findings of Mannion et al.[5] and 
Rankin et al.[7] The absolute muscle thickness of TA (4.6 - 5.3 cm) was 
slightly greater than that found by Mannion et al.[5] (3.9 - 4.0 cm), while 
the OI values (11.3 - 15.2 cm) in the present study were much higher 

Table 2. Absolute thickness at rest and percentage change* in thickness in ADIM, ASLR-L and ASLR-R activity positions of TA, OI 
and OE at the start v. the end of a cricket season (N=24)†

Non-dominant Dominant
Pre-season 
mean (±SD)

Post-season 
mean (±SD) p-value

Effect size 
Cohen’s d

Pre-season 
mean (±SD)

Post-season 
mean (±SD) p-value

Effect size 
Cohen’s d

TA
Rest (mm) 4.6 (±1.1) 4.9 (±1.4) 0.13 0.22 4.9 (±1.3) 5.3 (±1.4) 0.07 0.38
ADIM % change 55.8 (±46.2) 41.6 (±34.8) 0.13 0.35 41.7 (±32.3) 27.0 (±27.1) 0.07 0.51
ASLR-L % change 17.0 (±35.4) 15.8 (±26.6) 0.88 0.04 13.1 (±31.7) 5.7 (±21.9) 0.35 0.28
ASLR-R % change 23.8 (±34.8) 20.2 (±35.2) 0.67 0.11 16.7 (±27.3) 5.5 (±20.8) 0.06 0.47

OI
Rest (mm) 14.1 (±3.9) 15.2 (±3.4) 0.12 0.32 11.3 (±2.3) 11.9 (±2.7) 0.28 0.24
ADIM % change 12.6 (±20.4) 11.1 (±15.5) 0.75 0.08 2.0 (±22.1) 7.6 (±13.5) 0.25 0.31
ASLR-L % change 9.7 (±28.34) 14.1 (±19.3) 0.48 0.19 0.03 (±20.2) 7.7 (±21.5) 0.07 0.38
ASLR-R % change 8.7 (±20.7) 4.0 (±24.0) 0.45 0.21 4.7 (±18.6) 8.9 (±19.8) 0.41 0.22

OE
Rest (mm) 6.5 (±2.3) 7.4 (±2.6) 0.12 0.35 6.0 (1.4) 7.5 (±2.1) 0.00† 0.85

 
TA = transversus abdominis; OI = oblique abdominis internus; OE = oblique abdominis externus; ADIM = abdominal drawing-in manoeuvre; ASLR-L = active straight-leg raise (left);  
ASLR-R = active straight-leg raise (right); SD = standard deviation.

* Percentage change was calculated as a percentage of muscle thickness at rest: (muscle activated - muscle at rest) ÷ muscle at rest × 100.

†
 Significant differences between pre- and post-season (p<0.05).



84   SAJSM  vol. 25  No. 3  2013

and the OE values (6.0 - 7.5 cm) correspond closely to those found by 
Mannion et al. (OI: 8.3 - 8.6 cm; OE: 6.7 - 7.1 cm). Mannion et al.[5] 
used a non-sporting population consisting of volunteers and this may 
explain their participants’ lesser TA and OI thickness values. In contrast, 
Rankin et al.[7] found a mean TA thickness (4.5 - 5.1 cm) similar to what 
was found in the present study, with thinner OI (11.7 - 11.8 cm) and 
thicker OE muscles (9.6 - 9.7 cm) in moderately active volunteers. [7] 
Although Hides et al.[8] did not measure OE thickness, they found 
higher thickness values for both TA (6.8 - 7.2 cm) and OI (16.7 - 16.8 
cm) than in this study. The professional fast bowlers assessed in the 
latter study were likely to be able to devote more time to pace-bowling 
training and conditioning, which may lead to greater hypertrophy of 
the abdominal musculature than in elite players. These differences in 
OI absolute thickness suggest that the more active the population, the 
larger the OI values, and might indicate the particular activation of OI 
muscles during high load, repeated, asymmetrical physical activity. A 
similar trend was found in resting thickness for TA, but not for OE. It 
would appear that as the OI gets thicker, the OE gets thinner, thus the 
relative balance in resting muscle thickness changes as the activity of 
the individual changes. This hypothesis requires further study; however, 
the consistent methods used by the latter studies[5,7,8] might suggest that 
different abdominal muscles display far more complex responses to 
training than was previously thought.

In the current study, the absolute thickness of the OI at rest was 
significantly higher on the non-dominant side than on the dominant 

side, both at the start as well as at the end of the cricket season as 
shown in Table 1. The large effect sizes emphasise the significance 
of this finding. In contrast to the findings in our study, Mannion et 
al.[5] and Springer et al.[6] found no statistically significant differences 
between the left and right abdominal muscle thickness and Rankin et 
al.[7] found asymmetries in TA thickness only. In the case of Springer et 
al.[6] and Mannion et al.,[5] the researchers used a sample where no or 
few participants engaged in unilateral or rotational sporting activities. 
Springer et al.[6] suggest that individuals who routinely participate 
in rotational activities such as tennis and golf may be more likely to 
display asymmetries. Asymmetrical findings may increase the risk of 
developing pathology.[1] However, in a mathematical model used to 
estimate lumbar spinal stresses during quadratus lumborum muscle 
asymmetry, it was suggested that quadratus lumborum muscle 
asymmetry only causes small stresses and it may even help to reduce 
stress on the lumbar spine.[12] Participants in this study were all healthy, 
pain and injury-free at the time of testing, which may suggest that 
factors other than pathology are responsible for the asymmetries found, 
as suggested by De Visser et al.[12] These differences in absolute muscle 
thickness on the non-dominant and dominant sides may be as a result 
of long-term preferential use of the right bowling arm and subsequent 
preferential, asymmetrical recruitment of abdominal muscle fibres that 
may play a role in protection of the lumbar spine. It should, however, be 
noted that the asymmetries seen in pace bowlers are one of the factors 
predisposing them to their known susceptibility to lower-back injury,[1] 

25

20

15

10

5

0
TA OI

13.1

23.8

0

8.7

Right abdominal muscles
(ASLR-L)

Left abdominal muscles
(ASLR-R)

a

25

20

15

10

5

0

Right abdominal muscles
(ASLR-L)

Left abdominal muscles
(ASLR-R)

20.2

5.7
7.7

4

TA OI

c

TA OI

Right abdominal muscles
(ASLR-R)

Left abdominal muscles
(ASLR-L)

17 16.7

9.7

4.7

18

16

14

12

10

8

6

4

2

0

b

TA OI

15.8

5.5

14.1

8.9

18

16

14

12

10

8

6

4

2

0

Right abdominal muscles
(ASLR-R)

Left abdominal muscles
(ASLR-L)

d

Fig. 1. Percentage change in thickness measured in the ASLR-L (non-dominant) and ASLR-R (dominant) activity positions: (a) pre-season in 
contra-lateral muscles (TA: p=0.17; OI: p=0.13); (b) pre-season in ipsilateral muscles (TA: p=0.79; OI: p=0.48); (c) post-season in contra-lateral 
muscles (TA: p=0.03; OI: p=0.50); (d) post-season in ipsilateral muscles (TA: p=0.15; OI: p=0.31). 



SAJSM  vol. 25  No. 3  2013  85

but this asymmetry may also play a protective 
role.[12]

Taking the biomechanics of the pace-bowl-
ing action into account (Fig. 2), weight is 
put onto the non-dominant leg at front-foot 
placement when the ground reaction force 
is extremely high,[13] which may mean that 
the ipsilateral OI has to contract to assist in 
absorbing the ground reaction forces, taking 
into account the position of the pace bowler. 
In the present study, the absolute thickness of 
the non-dominant OI was greater than that 
of the dominant OI, which fits with the above 
theory. Also, while the non-dominant leg takes 
a vast amount of the load during the delivery 
stride, the dominant OE contracts in order 
to stabilise the pelvis in its typical cross-over 
activation fashion.[14] The repetitive nature of 

a pace bowler’s role in cricket training and in 
competition, resulting in many replicates of 
the bowling action, may explain the greater OE 
absolute thickness values found in this study 
at the end of the cricket season in comparison 
with the start of the cricket season (Table 2). 
Although this may explain the difference in 
absolute muscle thickness of the OI and OE 
at rest, it must be noted that activation levels 
between the non-dominant and dominant OI 
in asymmetrical ASLR-L and ASLR-R activity 
positions were not statistically significant.

During a symmetrical activity position 
(ADIM), the activation of the non-dominant 
OI is greater than that of the dominant side. 
Although this finding is only statistically 
significant for the pre-season measurements 
on OI, all other activation findings for OI 

and TA during the ADIM show that the 
abdominal muscles on the non-dominant 
side are activated at a higher rate than the 
dominant abdominal muscles. This may 
emphasise the repeated utilisation of the 
non-dominant TA and OI during the bowling 
action, and the subsequent preferential 
recruitment. The asymmetry of the bowling 
action may play a role in the development of 
habitual movement patterns maintained by 
pre-programmed motor-control pathways. [15] 
Furthermore, the activation of TA is higher 
than the activation of OI in the ADIM, 
ASLR-L and ASLR-R activity positions, 
which indicates that the TA is the preferential 
muscle recruited during sub-maximal muscle 
contraction.[10]

During asymmetrical activity positions, 
the left TA showed statistically significantly 
greater activity during the ASLR-R than 
the right TA during ASLR-L (Fig. 1). This 
was also clear during the ASLR-L, where 
the left TA activity was again much higher 
than the right TA activity during ASLR-R; 
although not statistically significant, it is of 
clinical significance. This finding indicates 
that the left TA activity is higher than the 
right TA activity during contra-lateral as 
well as ipsilateral activity positions. This is 
contradictory to a study by Teyhen et al.[11] 
which found that the TA is symmetrically 
activated during asymmetrical activity, while 
Hu et al.[14] found that TA and OI showed 
greater asymmetrical activity than OE. The 
difference in results can be attributed to the 
different populations studied, where Teyhen 
et al.[11] studied Department of Defence 
healthcare beneficiaries, including active-duty 
military family members and retirees, and Hu 
et al.[14] studied a group of females. Neither 
author specified details on specific sports 
participation. The difference in dominant and 
non-dominant TA activity is less pronounced 
during the pre-season measurements, which 
again shows that the intense training and 
repetition of the asymmetrical bowling action 
that takes place during a cricket season may 
be responsible for the preferential increase in 
activation of non-dominant TA. 

Study limitations
No comparison group of non-athletes was 
assessed in parallel to the pace bowlers in this 
study. Generalisation of the current findings 
is thus limited to cricket pace bowlers and 
future studies should be performed to 

Run-up

The bowler walks or jogs, gradually increasing
his speed, as he approaches the wicket.
The run-up ends as he leaps into the air at the
start of the pre-delivery stride. The run-up
length varies between 15 m and 30 m.

Pre-delivery stride

The bowler jumps o� his left foot and lands 
on the right or back foot. The shoulders are
pointing down the wicket.

Delivery stride

The bowler lands on his back foot with the
body leaning away from the batsman. The
delivery stride includes back-foot strike, front-
foot strike and ball release.

Follow-through

The bowling arm follows through down the
outside of the left thigh.

Fig. 2. The phases of the pace bowling action (reference made to a right-handed bowler).



86   SAJSM  vol. 25  No. 3  2013

compare abdominal muscle absolute thickness and activity in different 
sporting populations. Furthermore, studies should be done to assess 
the training components of the cricket season, the activation of the 
abdominal muscles during the pace-bowling action and its influence 
on abdominal muscle thickness. 

Conclusion
Our study highlights the possible muscle adaptations in absolute 
muscle thickness and activity as a consequence of the high load of 
asymmetrical bowling action that is performed repeatedly during 
matches and training. The type and intensity of training that took place 
during the cricket season may have accounted for the asymmetries in 
abdominal muscle thickness that were found at the end of the season. 

Acknowledgement. Funding was granted by the Carnegie Foundation, 
the  South African National Research Foundation and the South African 
Society of Physiotherapy.

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