Motriz, Rio Claro, v.20 n.3, p.303-309, July/Sept. 2014 DOI: dx.doi.org/10.1590/S1980-65742014000300009

303

Original article (short paper)
Vertical jump fatigue does not affect 

intersegmental coordination and  
segmental contribution

Gleber Pereira
Federal University of Paraná, Curitiba, Brazil

Paulo B. de Freitas
Jose A. Barela

Cruzeiro do Sul University, São Paulo, Brazil

Carlos Ugrinowitsch
University of São Paulo, Brazil

André L. F. Rodacki
Federal University of Paraná, Curitiba, Brazil

Eduardo Kokubun
São Paulo State University, Rio Claro, Brazil

Neil E. Fowler
Manchester Metropolitan University, Crewe, United Kingdon

Abstract—The aim of this study was to describe the intersegmental coordination and segmental contribution during 
intermittent vertical jumps performed until fatigue. Seven male visited the laboratory on two occasions: 1) the maximum 
vertical jump height was determined followed by vertical jumps habituation; 2) participants performed intermittent cou-
ntermovement jumps until fatigue. Kinematic and kinetic variables were recorded. The overall reduction in vertical jump 
height was 5,5%, while the movement duration increased 10% during the test. The thigh segment angle at movement 
reversal significantly increased as the exercise progressed. Non-significant effect of fatigue on movement synergy was 
found for the intersegmental coordination pattern. More than 90% of the intersegmental coordination was explained by 
one coordination pattern. Thigh rotation contributed the most to the intersegmental coordination pattern, with the trunk 
second and the shank the least. Therefore, one intersegmental coordination pattern is followed throughout the vertical 
jumps until fatigue and thigh rotation contributes the most to jump height.

Keywords: intermittent exercise, principal component analysis, psychomotor performance

Resumo—“Fadiga em salto vertical não afeta a coordenação intersegmental e contribuição segmental.” O objetivo deste 
estudo foi descrever a coordenação entre segmentos e suas contribuições durante saltos verticais intervalados realiza-
dos até a fadiga. Sete indivíduos visitaram o laboratório em duas ocasiões: 1) foi determinada a altura máxima do salto 
vertical e realizada familiarização com saltos verticais; 2) participantes realizaram saltos verticais em contramovimento 
até a fadiga. Foram coletadas variáveis cinemáticas e cinéticas. A altura do salto vertical reduziu 5,5% e duração do 
movimento aumentou 10%. O ângulo da coxa no instante de reversão do movimento aumentou durante o exercício. A 
fadiga na sinergia do movimento não influenciou na coordenação intersegmental. Acima de 90% da coordenação entre 
segmentos foi explicada por um padrão coordenativo. A rotação da coxa foi o que mais contribuiu com o padrão coorde-
nativo, seguido pelo tronco e perna. Portanto, em saltos verticais realizados até a fadiga, a coordenação intersegmental 
é mantida e a rotação da coxa tem maior contribuição na altura do salto.

Palavras-chave: exercício intervalado, análise do componente principal, desempenho psicomotor

Resumen—“Fatiga salto vertical no afecta a la coordinación entre segmentos y la contribución segmentaria.” El objetivo 
fue describir la coordinación entre los segmentos y sus contribuciones durante los saltos verticales realizadas hasta la 
fatiga. Siete sujetos visitaron laboratorio dos ocasiones: 1) determinó la máxima altura en el salto vertical y amistad con 



G. Pereira, P.B. Freitas, J.A. Barela, C. Ugrinowitsch, A.L.F. Rodacki, E. Kokubun & N.E. Fowler

Motriz, Rio Claro, v.20 n.3, p.303-309, July/Sept. 2014304

los saltos verticales; 2) participantes completaron saltos verticales contramovimento la fatiga. Se recogieron las varia-
bles cinemáticas y cinéticas. La altura del salto vertical disminuyó 5,5% y la duración del movimiento se incrementó 
10%. El ángulo del muslo en instante de inversión del movimiento aumentó durante ejercicio. No hubo efecto de fatiga 
en sinergia de movimiento para la coordinación de movimientos. Más del 90% de coordinación entre sectores ha sido 
explicado por un patrón coordinativo. La rotación del muslo fue mayor contribuyente la coordinación de movimientos, 
seguido por tronco y piernas. En los saltos verticales realizados hasta la fatiga se mantiene coordinación entre segmentos 
y rotación del muslo tiene mayor contribución en altura del tacón.

Palabras clave: año de intervalo, análisis de componentes principales, comportamiento psicomotor

ght (e.g., 95% of maximum vertical jump height) until fatigue 
(i.e., inability to sustain the target height for three consecutive 
jumps). Changes in the rest interval could postpone the fatigue, 
increasing the number of vertical jumps performed, and change 
the source of fatigue (Pereira, et al., 2009b). Furthermore, this 
experimental approach allows for more realistic assessment of 
intersegmental vertical jump coordination as the intermittent 
unconstrained countermovement jumps do not neglect the 
contribution of the trunk segment as jumps performed in the 
sledge apparatus does.

It is reported that the restriction of ankle joint movement 
during vertical jumping increased the power and work output 
at the knee joint (Arakawa, Nagano, Hay, & Kanehisa, 2013). 
A large part of the enhanced output at the knee is assumed to 
be from ankle restriction, which results in the nullification of 
energy transportation via muscle gastrocnemius, i.e., reduced 
contribution of the energy transfer with ankle restriction appe-
ared as augmentation at the knee joint. Then, as the number of 
intermittent vertical jumps progresses, the fatigue can decrease 
the muscle capability to generate force, leading to changes in 
joint contribution and intersegmental coordination. Alternati-
vely, the maximal characteristic of the vertical jump may limit 
itself the coordination changes, while segmental contributions 
would change seeking to maintain the power output (i.e., jump 
height). Therefore, the aim of this study was to describe the 
intersegmental coordination and segmental contribution during 
intermittent vertical jumps performed until fatigue. It was hypo-
thesized that exercise-induced fatigue would change vertical 
jump intersegmental coordination and segmental contribution 
of lower limbs.

Methods

Seven healthy male participants (mean ± SD; 23.9 ± 1.8 
years; 74.5 ± 7.7 kg; 178 ± 6 cm), engaged in recreational 
volleyball practice, volunteered to participate in this study. 
Participants were asked to refrain from severe physical activity 
in the day before each experimental session. This study was 
previously approved by the Research Ethics Committee, which 
also provided the Ethical Guidelines followed in this study. 
Participants were informed about the procedures, benefits and 
risks before giving and signing the written informed consent.

Participants visited the laboratory on two occasions separa-
ted by a period of three days. In the first session, the maximum 
vertical jump height was determined followed by vertical jumps 
habituation. Participants performed five maximum vertical 

Introduction

Vertical jumping is an essential component of several sports. 
As such, this motor skill is frequently performed leading to 
fatigue. It is known that vertical jumping-induced fatigue alters 
muscle properties (Bojsen-Moller, Magnusson, Rasmussen, 
Kjaer, & Aagaard, 2005; Ishikawa, et al., 2006b) and, conse-
quently, the ability to generate maximum or near maximum 
joint torques. However, a high vertical jump performance 
(i.e., jumping height) requires optimization of the movement 
coordination; that is, tuning control of the musculoskeletal 
properties (Bobbert, Krogt, Doorn, & Ruiter, 2011). Therefo-
re, fatigue may be a trigger to the central nervous system to 
modify the intersegmental body coordination responsible for 
vertical jump performance (van Ingen Schenau, van Soest, 
Gabreels, & Horstink, 1995).

The effect of fatigue on movement coordination has already 
been investigated during jumping adapted conditions in sledge 
apparatus (Horita, Komi, Hamalainen, & Avela, 2003; Horita, 
Komi, Nicol, & Kyrolainen, 1999; Kuitunen, Avela, Kyrolainen, 
Nicol, & Komi, 2002). It has been reported a decreased knee 
and ankle power after continuous rebounds and no changes in 
the contribution of the lower limb joints’ extension, even under 
decreased muscle force production capacity (Horita, et al., 2003; 
Horita, et al., 1999; Kuitunen, et al., 2002). Although these stu-
dies have greatly contributed to the understanding of the fatigue 
mechanisms involved in movements that simulate a vertical 
jump, less attention has been devoted to reveal possible changes 
in movement coordination. It is mainly because the movements 
performed in the sledge apparatus impose a significant constraint 
that limits the extension of the hip joint (i.e., leaning the trunk 
forward). This limitation may greatly affect jumping interseg-
mental coordination, as most of the work performed by the hip 
joint during countermovement jumps is devoted to accelerate 
the trunk upward (Bobbert & Van Soest, 1994). Moreover, the 
fatigue induced in the sledge apparatus has been investigated 
using either continuous or rebound jumps (Horita, et al., 2003; 
Kuitunen, et al., 2002; Rodacki, Fowler, & Bennett, 2001). 
However, it fails to mimic the intermittent condition observed 
in some sports (e.g., volleyball and basketball), in which there 
is an interval between subsequent vertical jumps.

A new method to investigate physiological and biomecha-
nical effects of fatigue on vertical jump was recently developed 
(Pereira, et al., 2011; Pereira, et al., 2009a; Pereira, et al., 
2009b). This method has the advantage to allow vertical jump 
assessment close to real sports condition. Shortly, the individuals 
perform countermovement jumps intermittently at a fixed hei-



Vertical jump fatigue

Motriz, Rio Claro, v.20 n.3, p.303-309, July/Sept. 2014 305

jumps with 1 minute resting interval between each jump. The 
maximum jump height was determined from the average of 
the five trials, because humans are able to achieve maximum 
power/strength in only 5% of their attempts. Thus, using 95% 
of the maximum jumping height as a target height during the 
fatigue protocol imposed a challenge to the participants that 
could be feasible (i.e., maintaining a given jumping height for 
a long period of time). The vertical jump habituation consisted 
of a set of jumps with a specific rest period length (6 s). This 
rest period length was chosen based on a previous study from 
our group (Pereira, et al., 2009b). According to the number of 
vertical jumps in this session, the rest period length for each 
individual was determined (increased or decreased ~2 s) to en-
sure that participants would perform approximately 80 jumps. 
In the second session, participants were asked to perform 
intermittent countermovement jumps with a fixed rest interval 
individually determined (7.4 ± 1.6 s) with arms crossed in front 
of their chest to the target height set at 95% of their maximum 
jump height (Pereira, et al., 2009b). Participants received visual 
feedback (on the monitor positioned in front of them) of their 
jump height immediately after each jump, which was estimated 
by impulse-moment method using customized LabView routine 
(National Instruments, Austin, Texas). Tests were halted when 
participants failed to reach the required height for three conse-
cutive jumps. Kinematic and kinetic variables were recorded 
for all vertical jumps.

Infrared emitters were placed on the right side of each par-
ticipant’s body in the following sites: 1) lateral malleolus, 2) 
lateral femoral epicondyle of the knee, 3) the most prominent 
protuberance of the greater trochanter, and 4) acromion process. 
The optoelectric system (Optotrak 3020 – 3D Motion Measure-
ment System, NDI) was used to record (200 Hz) the x, y and z 
coordinates of the IRED position and they were filtered using 
a zero lag, fourth order, and low pass digital Butterworth filter. 
Cut-off frequency was defined by residual analysis and set at 
7 Hz (Winter, 2005). The coordinates of the joint points were 
used to calculate segment angular displacement of the shank, 
thigh and trunk (Figure 1). 

A force platform (Kistler, model 9286A, Winterthur, Swit-
zerland) was synchronized with the kinematic data measure-
ments and sampled at 1000 Hz to provide force-time traces. The 
data were filtered using a zero lag, fourth order, and low pass 
digital Butterworth filter. Cut-off frequency was also defined 
by residual analysis and set at 13 Hz (Winter, 2005).

A custom MatlabTM routine was written to process and 
analyze the kinematic and kinetic data. The movement duration 
was defined from the beginning of eccentric phase to the takeoff 
instant. Movement duration was divided into two phases: the 
eccentric and concentric phase. The beginning of eccentric phase 
was defined as the instant when the vertical force decreased by 
2% of body weight (eccentric phase beginning = body weight – 
(0.02·body weight)). Body weight was determined by averaging 
vertical force measured for 2 s during a quiet stance before the 
jumping protocol (Vanrenterghem, De Clercq, & Van Cleven, 
2001). The end of the eccentric phase corresponded to the be-
ginning of concentric phase and was defined as the instant in 
which the net velocity of the center of mass crossed zero after 
the unweighting phase (Bosco, & Komi, 1979). At this instant 
(movement reversal), body segment angles were determined. 
The end of concentric phase was determined when participants 
lost contact with the force platform (takeoff). The takeoff veloci-
ty consisted of the whole body velocity immediately before the 
takeoff, calculated from the net concentric impulse computed 
by using the impulse-momentum theorem (Linthorne, 2001). 
Jump height was calculated from the takeoff velocity using the 
equations of uniform accelerated motion.

A statistical tool known as principal component (PC) analy-
sis (Daffertshofer, Lamoth, Meijer, & Beker, 2004) has been 
used to assess intersegmental coordination during movement 
performance. The PC analysis was already used in the investiga-
tion of intersegmental coordination in postural control (Freitas, 
Latash, & Duarte, 2006; Krishnamoorthy, Yang, & Scholz, 2005) 
and gait (Borghese, Bianchi, & Lacquaniti, 1996; Mah, Hulliger, 
Lee, & O’Callaghan, 1994). Therefore, intersegmental coordi-
nation (i.e., the relationship among body segments involved in 
the vertical jump) was assessed using PC analysis on the linear 
co-variation of sagittal plane shank, thigh and trunk segment 
angles from the beginning of the eccentric phase to the end of 
the concentric phase. The percentage of variance explained by 
each principal component (total of 3) and the contribution (PC 
loading factors) of shank, thigh, and trunk segment angles for 
each component were analyzed. The average of three vertical 
jumps performed in the beginning (from the fourth to the sixth 
jump), middle (the vertical jump at 50% position, and one jump 
before and after that) and end of the session (last three jumps) 
were considered for analysis to identify possible changes due 
to muscle fatigue.

After confirming the normality and homogeneity of variance 
(Shapiro-Wilk and Levene test, respectively), jumping height, 
vertical jump duration, and segment angle at movement reversal 
were compared between different instants (beginning, middle 
and end phases) with one-way repeated measures analyses of 
variance (ANOVAs). Additional one-way repeated measures 
ANOVA was employed to test the effect of fatigue (beginning, 
middle, and end) on the explained variance by the first PC, 

Figure 1. Convention used to define shank, thigh and trunk segmental 
angles (j).



G. Pereira, P.B. Freitas, J.A. Barela, C. Ugrinowitsch, A.L.F. Rodacki, E. Kokubun & N.E. Fowler

Motriz, Rio Claro, v.20 n.3, p.303-309, July/Sept. 2014306

which explained more than 90% of the vertical jump segmental 
synergy. Finally, two-way repeated measures ANOVAs were 
carried out to test the effect of fatigue and segmental angle 
(shank, thigh, and trunk) on the loading factors (absolute Fisher 
z-transformed values) from the first PC. Post-hoc tests with 
Bonferroni corrections were used for multi-comparison purposes 
when necessary. Significance level was set at p < .05. Data are 
presented as mean ± SD.

Results

The vertical jump height decreased significantly from the 
beginning to the middle (-2.5%) and from the middle to the end 
of the test (-4.1%) (Figure 2A). The overall fall in vertical jump 
height (from the beginning to the end of the test) was -5.5% 
(p < .001). In addition, the vertical jump duration followed an 
inverse pattern of jump height, time increased significantly 
from the beginning to the middle (5.1%) and from the middle 
to the end (5.1%). The movement duration increased by 10.2% 
(p < .001) from the beginning to the end of the test (Figure 2B).

Non-significant effect (p = .09) of fatigue on movement 
synergy was presented on the first PC (Figure 3A). In order 
to test the contribution of each segment movement to the first 
PC, a two-way repeated measure ANOVA (time to fatigue vs. 
segment) presented no interaction (p = .40) or time effect (p = 
.60), but presented an effect of segment on the loading factors 
(p < .001). Post-hoc tests showed that the thigh rotation con-
tributed the most to the first PC, with the trunk second and the 
shank the least (Figure 3B).

Figure 2. Vertical jump height (A) and duration (B) in different time. A: 
adifferent from the end (p < .001); bdifferent from the middle (p = .018). 
B: adifferent from the end (p = .04); bdifferent from the middle (p = .03).

Figure 3. (A) Percentage of variance explained by the first principal 
component (PC1) for all instants (A). (B) It shows the contribution 
(loading) of each segment to the first PC. adifferent from thigh (p < 
.01); bdifferent from trunk (p < .001).



Vertical jump fatigue

Motriz, Rio Claro, v.20 n.3, p.303-309, July/Sept. 2014 307

ver, it was smaller than the one reported after continuous vertical 
jump fatigue (-30%) (Rodacki, et al., 2001), after knee extensors 
(-14%) (Rodacki, Fowler, & Bennett, 2002) and plantar flexors 
(-18%) (Bobbert, et al., 2011) muscle fatigue. Thus, different 
vertical jump fatiguing protocols (intermittent vs. continuous 
exercise, isolated vs. whole muscle groups, or test interruption 
criterion) may explain such discrepancies in vertical jump per-
formance reductions. Furthermore, the performance reductions 
in the present study are closer to game/training conditions of 
sports, based on the intermittency of our fatigue protocol. The 
vertical jump-induced fatigue protocol used in this study mimics 
the fatigue level reported by previous study, which described 
a reduced jump performance (-7.5%) when volleyball players 
performed intermittent volleyball attacks with resting period 
length similar to real match conditions (Pereira, et al., 2008). 
Hence, the changes or conservations of movement synergies/
contributions, which are approached below, may be considered 
closer to actual sports condition. 

The vertical jump duration (i.e., summation of eccentric and 
concentric phases) increased significantly during the fatiguing 
protocol. It can be interpreted as movement adjustment to sus-
tain the required target height (Hortobagyi, Lambert, & Kroll, 
1991). The net impulse, mainly generated during concentric 
phase, is closely related to vertical velocity of center of mass at 
the takeoff, and this is related to the height achieved by center 
of mass during the flight phase. Therefore, the maintenance of 
jump height depends on the maintenance of net impulse. Since 
great amplitude of vertical ground reaction force has not been 
sustained under fatigue (Pereira, et al., 2009a), a longer vertical 
jump duration was a strategy used to maintain the net impulse 
during fatigue, in order to maintain jump performance.

The increased vertical jump duration can also be a result of 
larger range of motion at the joints and/or increased joint reversal 
time (Hortobagyi, et al., 1991). In the present study, the thigh 
segment angle at movement reversal increased significantly 
(greater counterclockwise rotation) as the exercise progressed, 
explaining the increased movement duration. However, mus-
cle contractile impairments may also influence on movement 
duration (Rodacki, et al., 2001). Such impairments have been 
reported on stretch-shortening cycle exercise-induced fatigue 
protocols performing simulated jumps (Horita, et al., 2003; Ishi-
kawa, et al., 2006b) or real intermittent vertical jumps (Pereira, 
et al., 2009b). In addition, the muscle stiffness and tendinous 
tissue compliance have changed after stretch-shortening cycle 
fatigue (Ishikawa, et al., 2006a). The passive muscle stiffness 
usually increases after eccentric exercise (Ishikawa, et al., 
2006a) and it is determined by the non-contractile elements in 
the muscle, such as titin and desmin, which form elastic links 
between the thick filaments and Z-lines (Lieber, Thornel, & 
Friden, 1996). Thus, changes in the strain of these links after the 
exhausting stretch-shortening cycle fatigue exercises might lead 
to different passive tension slope during the exercise. Moreover, 
the concentric and isometric muscle function may be affected 
by the increased tendinous tissue compliance (Ishikawa, et al., 
2006a). Therefore, both greater counterclockwise rotations 
of the thigh and muscle contractile changes could explain the 
movement duration increases.

The shank and trunk segment angles at movement reversal 
(transition from eccentric to concentric phase) did not differ 
significantly across the beginning (shank = 55°; trunk = 42°), 
middle (shank = 53°; trunk = 39°), and end instants (shank = 
52°; trunk = 39°) (p = .08). However, the thigh segment angle 
at movement reversal was significantly increased (greater 
counterclockwise/backwards rotation) at the middle (4%) and 
end (4%) instants compared to the beginning instant (Figure 4).

Discussion

The aim of this study was to describe the intersegmental 
coordination and segment contributions during intermittent 
vertical jumps performed until fatigue. More than 90% of the 
intersegmental coordination was explained by one principal 
component, indicating that one movement synergy was respon-
sible for the performance of the vertical jump during the process 
of fatigue. In addition, the segment contribution did not change 
during the fatigue process, with the thigh segment contributing 
the most and the shank segment the least to vertical jump.

In the present study, the fatigue protocol implied that jump 
performance (jump height) would decrease due to intermittent 
vertical jump repetitive execution. The average performance 
reduction (-5.5%) was similar to the one reported using similar 
exercise fatigue protocol (-6.7%) (Pereira, et al., 2009a). Howe-

Figure 4. Segment angle at movement reversal in different time of 
shank (A), thigh (B) and trunk (C). adifferent from the end (p < .001); 
bdifferent from the middle (p < .001).



G. Pereira, P.B. Freitas, J.A. Barela, C. Ugrinowitsch, A.L.F. Rodacki, E. Kokubun & N.E. Fowler

Motriz, Rio Claro, v.20 n.3, p.303-309, July/Sept. 2014308

It has been reported that maximal voluntary isometric con-
traction of the quadriceps muscle decreases after using similar 
fatiguing protocol (Pereira, et al., 2009b). Hence, one may 
expect that segment synergies would change during vertical 
jump-induced fatigue, in order to compensate the force reduc-
tion. However, the first principal component explained more 
than 90% of the vertical jump movement during the fatigue 
protocol. It means that an optimal intersegmental coordinative 
pattern was maintained from the beginning (non-fatigued condi-
tion) to the end (fatigued condition) of exercise, irrespective of 
muscle fatigue. Similar finding has been reported when fatigue 
was induced using continuous vertical jumps (Rodacki, et al., 
2001). Then, it suggests that the vertical jump performed closer 
to the maximum height (95%) has a specific/strict movement 
pattern that does not change under fatigue. This optimal solution 
could be built by practice and even during adverse conditions 
(e.g., fatigue) it could not be dramatically changed.

The segment contributions of vertical jump did not change 
during the intermittent vertical jump-induced fatigue protocol. 
The thigh rotation contributed the most to the first principal 
component, with the trunk second and the shank the least. It 
was hypothesized that segment contributions would change 
during fatigue, since the maximal voluntary isometric torque of 
the quadriceps muscle is reduced after similar fatigue protocol 
(Pereira, et al., 2009b). One explanation for this result is that 
the jump height required in our study was very close to the 
maximum and the movement pattern was not changed to com-
pensate the force loss. In addition, the constraint can reduce the 
movement degrees of freedom (Van Soest, & Van Galen, 1995). 
Then, as muscle fatigue is considered a constraint, the degrees 
of freedom of the vertical jump could reduce from two to one, 
decreasing drastically the possibility of changing the segment 
contributions and segmental synergies.

The results have some practical implications, which are: 
performing intermittent vertical jumps with approximately seven 
seconds between them can decrease the number of vertical jumps 
at fixed height. Fatigue does not change the segment contribu-
tions and segmental synergies, regardless of the reduction in 
jumping height. Implementing intermittent vertical jumps may 
be an alternative training paradigm to maintain jump height 
level during the session. However, the readers should consider 
the number of participants in this study, which hampers the 
external validity of our findings.

Conclusion

The same intersegmental coordination pattern is followed 
throughout the vertical jumps performed until fatigue. In addi-
tion, the contributions of the lower limb segments were main-
tained throughout the vertical jumps, while the thigh rotation 
contributed the most to jump height.

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Motriz, Rio Claro, v.20 n.3, p.303-309, July/Sept. 2014 309

Carlos Ugrinowitsch is affiliated with the Department of Sport, School of 
Physical Education and Sport, University of São Paulo, São Paulo, Brazil
André L F Rodacki is affiliated with the graduate program in Physical 
Education at the Federal University of Paraná, Curitiba, Brazil

Eduardo Kokubun is affiliated with the Department of Physical Edu-
cation, São Paulo State University, Rio Claro, Brazil

Neil E Fowler is affiliated with the Department of Exercise and Sport 
Science, Manchester Metropolitan University, Crewe, United Kingdon

Corresponding author

Gleber Pereira
Universidade Federal do Paraná
Departamento de Educação Física
Programa de Pós-Graduação em Educação Física
Rua Coração de Maria, 92 - BR 116 km 95
Jardim Botânico, Curitiba 80215-370 Paraná, Brazil
Phone: 55 41 3360-4333
Fax: 55 41 3360-4336
Email: gleber.pereira@gmail.com

Acknowledgements

CAPES and CNPq

Manuscript received on March 11, 2014
Manuscript accepted on August 5, 2014

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Authors’ note

Gleber Pereira is affiliated with the Núcleo de Ciências Biológicas e da 
Saúde, Universidade Positivo, Curitiba, and the graduate program in 
Physical Education at the Federal University of Paraná, Curitiba, Brazil

Paulo B de Freitas and Jose A. Barela are affiliated with the Institute 
of Physical Activity and Sport Sciences, Graduate Program in Human 
Movement Science, Cruzeiro do Sul University, São Paulo, Brazil