Center of pressure-based postural sway differences on parallel and single leg stance in Olympic deaf basketball and volleyball players

Article information

J Exerc Rehabil Vol. 17, No. 6, 418-427, December, 2021
Publication date (electronic) : 2021 December 27
doi : https://doi.org/10.12965/jer.2142558.279
Faculty of Sports Sciences, Karamanoğlu Mehmetbey University, Karaman, Turkey
*Corresponding author: Yücel Makaracı Faculty of Sport Sciences, Karamanoğlu Mehmetbey University, Karaman 70200, Turkey, Email: yucelmkrc@gmail.com
Received 2021 September 23; Accepted 2021 October 22.

Abstract

In sports such as basketball and volleyball, loss of balance due to the inability to maintain body stability and lack of postural control adversely affect athletic performance. Deaf athletes appear to struggle with balance and postural stability problems. The purpose of this study was to examine postural sway values in parallel and single leg stance of Olympic deaf basketball and volleyball players and reveal differences between the branches. Twenty-three male athletes from the Turkish national deaf basketball (n=11) and volleyball (n=12) teams participated in the study. After anthropometric measurements, the subjects completed postural sway (PS) tests in parallel/single leg stances with open eyes and closed eyes on a force plate. PS parameters (sway path, velocity, and area) obtained from the device software were used for the statistical analysis. The Mann-Whitney U-test was used to compare differences in PS parameters between basketball and volleyball players, and the alpha value was accepted as 0.05. Volleyball players had significantly better results in parallel stance and dominant leg PS values than basketball players (P<0.05). There was no significant difference between the groups in nondominant leg PS values (P>0.05). We think that proprioceptive and vestibular system enhancing training practices to be performed with stability exercises will be beneficial in terms of both promoting functional stability and interlimb coordination. Trainers and strength coaches should be aware of differences in the postural control mechanism of deaf athletes.

INTRODUCTION

Hearing loss, which is defined as a problem in the ossicles of the middle ear in the transmission of sound, is stated as one of the most common types of disability, and there are approximately 360 million deaf individuals in the world, according to the World Health Organization (WHO) (Vita and Bruno, 2021; Zakeri and Taghian, 2020). Although hearing loss or impairment is mostly a communication-related problem, it can also be associated with other health factors such as balance defects or damage of sensory integration and motor development (Carpenter and Campos, 2020). Moreover, people with hearing impairment have difficulty performing daily balance-based activities (Gheysen et al., 2008). Sports are considered an important means of preventing medical problems of deaf individuals resulting from hearing loss and possible communication problems (Kurková et al., 2011). In recent years, it has been observed that participation in sports branches designed for individuals with disabilities and specially organized competitions has increased (McLoughlin et al., 2017). Although disabled individuals have disadvantages in terms of sports, the modification of sports branches according to the type of disability minimizes the difficulties caused by the disability and provides the requirements of the branch at an optimum level (Akınoğlu and Kocahan, 2019a). Among disabled athletes, those who are deaf participate in sports competitions without any restrictions because they do not have any physical deficiencies (Kurková et al., 2011).

It has been reported that the proper functioning of hearing organs significantly depends on postural stability (Walicka-Cupryś et al., 2014). In this context, body stabilization is a concept that comes to the fore when examining the athletic performance levels of deaf athletes participating in physical activities or sports competitions. For the body to stay upright and maintain this position, the sensory system must function faultlessly (Asadi et al., 2015; Hansson et al., 2010). Balance and postural stability are the basis of voluntary motor activities. Therefore, together with the integration of sensory outputs such as visual, vestibular, and proprioceptive ones, the harmony of motor and visual neurophysiological mechanisms is a requirement for postural stability (de Sousa et al., 2012). Considering the effect of the vestibular system on postural control, it is clear that possible vestibular problems will affect postural control adversely. A lack of postural control or swaying to a certain side (mediolateral, anteroposterior, etc.) limits basic sporting skills (Burke-Doe et al., 2008). Accordingly, Akınoğlu and Kocahan (2019b) stated that stabilization and balance training positively affected muscle strength and balance in deaf karate athletes. Zarei and Norasteh (2021) reported that an 8-week stability training program improved trunk muscle endurance in deaf individuals. Zarei et al. (2020) also indicated that 8-week pilates training significantly improved balance in female deaf students. As a result, it is evident that the concept of postural control should be the focus when the performance outputs of deaf athletes are evaluated.

Performance of the balance/postural control system is commonly evaluated in the laboratory by quantifying sway during a quiet upright stance. The most commonly used measures of postural sway are varied parameters derived from temporal patterns of the center of pressure (CoP) (Lin et al., 2008). Traditional assessment of CoP-based postural sway measures involve the measurements during different stance types and durations. CoP data across longer trials increases the reliability of the measurements (Kozinc et al., 2021). Sway path, sway area, sway velocity (anterior-posterior; medial-lateral), and ellipse area are some of the common CoP-based measures and especially have been related to postural stability and the risk of falls (Greene et al., 2012; Roman-Liu, 2018; Vsetecková and Drey, 2013). In athletes, postural control contributes to developing specific postural strategies required by a specific sport and acquiring new abilities in balance control according to the discipline of the training practiced on athletes. Studies investigating postural control in basketball and volleyball players are gaining importance in this respect. Loss of balance that may arise due to the inability to maintain body stability in sports such as basketball and volleyball, which heavily involve side steps, changing direction, stopping/acceleration, and sudden (vertical/horizontal) jumps, adversely affects athletic performance (motoric skills) (Agostini et al., 2013; Zemková and Hamar, 2014) because athletes perform numerous jumping/landing and sprint-based movements during competitions or training (Taylor et al., 2017). Therefore, balance is considered a natural requirement in exhibiting motoric movements (Hrysomallis, 2011).

The present study will contribute to the literature, which contains a limited number of studies, since it focuses on reflecting a concept characterized by the vestibular system, such as postural control, in Olympic deaf athletes. The purpose of this study was to examine postural sway values in parallel and single leg stance of Olympic deaf basketball and volleyball players and reveal differences between the branches.

MATERIALS AND METHODS

Study design

A purposive sampling method was used to investigate the postural sway values of the national deaf men’s team basketball and volleyball players. All subjects completed postural sway tests under different conditions: (a) parallel stance open eyes (OE), (b) parallel stance closed eyes (CE), (c) single leg stance OE, and (d) single leg stance CE on a force plate device detailed below. The athletes performed a 10-min general warm-up phase before starting the test. The subjects were tested twice consecutively in each stance, and the average of the two test administrations was used to calculate the test results. The subjects did not perform any exercise and training programs during the study period. To reduce the interference of uncontrolled variables, all subjects were instructed to maintain their usual way of life and routine diet program intake before and during the study. During the testing, only water was allowed as a drink.

The study was conducted before the 2021 European Deaf Basketball and World Volleyball Championship camping period of the athletes. The measurements were taken at the same time of day (i.e., mid-day) by the same researcher to control the effects of the circadian rhythm. A sign language translator in the interaction with hearing-impaired players was present throughout the study to explain the test procedures. A separate familiarization session before the testing day was not deemed necessary since this is not required with participants of this level (Makaracı et al., 2021; Psycharakis et al., 2019).

Participants

Twenty-three male athletes from the Turkish national deaf basketball (n=11; age, 25.18±4.57 years; all with the dominant right leg) and volleyball (n=12; age, 24.42±4.42 years; all with the dominant right leg) teams participated in the study. The selection criteria of the athletes were as follows: being older than 18 years old, having a medically diagnosed hearing impairment condition (a hearing level in both ears >55 dB without cochlear implantation), ability to understand basic instructions, being a member of the 2021 national deaf men’s basketball and/or volleyball team, being a basketball and/or volleyball player for at least 3 years, and volunteering to participate in this study. The elimination criteria included the following: suffering from cervical and/or lumbar disc herniation, having any kind of orthopedic problem, having a recent acute injury causing cognitive, physical, or visual impairments, and having any neurological, orthopedic, or cardiovascular diseases.

All subjects signed informed consent forms. Ethical approval (Document No: 26794, 2021) was obtained from the Clinical Research Ethics Committee of Karamanoğlu Mehmetbey University, in accordance with the Declaration of Helsinki.

Anthropometric variables

The athletes’ body weight was measured by a force plate (automatically before testing), and their height was measured by a stadiometer (SECA-Mod. 220, Seca GmbH & Co. KG., Hamburg, Germany). The formula used to calculate the body mass index (BMI) is weight in kilograms (kg) divided by height in meters (m) squared (Makaracı et al., 2021).

Postural sway assessment

A force plate (Kistler, type 5691A, 40 cm×60 cm; Winterthur, Switzerland) was used to assess postural sway by determining CoP for each subject and calculating the difference in range over time. The forces are measured in three axes, x, y, and z.

Firstly, parallel stance (feet apart), then single leg stance (dominant and nondominant legs) postural sway values of the subjects were measured. In a parallel stance, the subject is standing in the center of the force plate with the feet placed close together and shifted longitudinally against each other. In a single leg stance, the subject is standing on one leg in the center of the force plate. The foot is oriented in the anterioposterior direction (along the Y-axis of the force plate), with the toes pointing anteriorly (+Y). Throughout the measurement, the subject sustains his normal upright stance position and places his hands on the hips. All measurements were conducted in OE and CE conditions. During the OE standing conditions, the participants were instructed to focus on an “x” placed at eye level on the wall in front of them. Since shorter time intervals during the body sway measurements are associated with lower reliability (Kozinc et al., 2021), we chose to analyze body sway by comparing 30-sec intervals during the parallel stance (Sturnieks et al., 2011). A 10-sec duration was selected during single leg stance tests due to the difficulty of testing (Goetschius et al., 2018). The subjects wore walking shoes and were asked to stand still and keep their arms at their sides.

The force plate collected ground reaction forces at a 120-Hz sampling frequency. The CoP measures included CoP path length, mean velocity and area. The postural sway parameters obtained from the Kistler Measurement, Analysis and Reporting Software (MARS, v4.0.2.99) were used for statistical analysis (Table 1). Diagrams referring to a single study participant during each standing condition are shown in Fig. 1.

Summary of the outcome postural sway measures, abbreviation, and descriptions

Fig. 1

Representative postural sway diagram from a single study participant during each standing conditions. The postural sway parameters obtained from the Kistler Measurement, Analysis and Reporting Software.

Statistical analysis

Before starting this study, a power analysis was performed to determine the number of athletes required, and a sample size of 10 athletes per group was estimated to have a power of 0.95 at α= 0.05. The statistics of descriptive variables (age, height, weight, and BMI) were reported using mean and standard deviation (mean±SD). The normality of distribution was tested by the Kolmogorov–Smirnov test and skewness/kurtosis values. Since our data were not normally distributed, the Mann-Whitney U-test was conducted to compare differences in the mean values of postural sway parameters between basketball and volleyball players. IBM SPSS Statistics ver. 24.0 (IBM Co., Armonk, NY, USA) was used for statistical data analyses. For all analyses, the threshold for statistical significance was set at P<0.05. Effect sizes (ES) are reported based on Cohen recommendations: where 0.2–0.49 is a small effect, 0.5–0.79 is a moderate effect, and ≥0.8 is a large effect (Nunes et al., 2021).

RESULTS

Baseline characteristics are presented in Table 2, and there are no significant differences between the groups (basketball and volleyball players) (P>0.05). Table 2 presents the characteristics related to age, height, weight, and BMI of the subjects. The results show no significant differences between the age, height, weight, and BMI of the groups.

Comparison of demographics variables of the groups

OE and CE parallel stance postural sway parameters of the athletes and the comparison results between the groups are shown in Table 3. When the parallel stance measurements performed with OE in Table 3 were examined, a statistical difference was observed in the values of Sway Path-T, Sway Path-ML, Sway V-T, Sway V-AP, Sway V-ML, Sway Area-ML, and EA-CoP between the groups (P≤0.05). The difference in the parameters of Sway Path-T, Sway Path-ML, Sway V-T, Sway V-AP, Sway V-ML, and EA-CoP was found to be a “large effect (ES=1.67, 1.03, 0.99, 1.10, 1.35, 1.23, respectively)” and the difference in the Sway Area-ML parameter was found to be a “moderate effect (ES=0.78)” according to the “effect size (Cohen d)” classification. In the difference between the groups, the arithmetic mean values of volleyball players are observed to be lower. This result indicates that volleyball players are in a better condition than basketball players in terms of parallel stance postural sway. In the postural sway measurements performed with CE, no statistical difference was observed in the values between the groups (P>0.05).

Parallel stance postural sway results of athletes

OE and CE dominant leg postural sway parameters of the athletes and the comparison results between the groups are shown in Table 4. When the dominant leg measurements performed with CE in Table 4 were examined, a statistical difference was observed in the values of Sway Path-T, Sway Path-AP, Sway V-T, and Sway V-AP between the groups (P≤0.05). The difference in the parameters of Sway Path-T, Sway Path-AP, and Sway V-AP was found to be a “large effect (ES=1.59, 0.88, 0.90, respectively),” and the difference in the Sway V-T parameter was found to be a “moderate effect (ES=0.77)” according to the “effect size (Cohen d)” classification. In the difference between the groups, the arithmetic mean values of volleyball players are observed to be lower. This result indicates that volleyball players are in a better condition than basketball players in terms of dominant leg postural sway. In the postural sway measurements performed with OE, no statistical difference was observed in the values between the groups (P>0.05).

Dominant leg (right) postural sway results of athletes

Statistically significant dominant leg postural sway findings of the athletes are presented in Fig. 2. Fig. 2 shows that the Sway Path-T, Sway Path-AP, Sway V-T, and Sway V-AP parameters of the dominant leg were significantly lower in volleyball players than basketball players (P=0.001, P=0.037, P=0.048, and P= 0.028, respectively).

Fig. 2

Statistically significant dominant leg postural sway findings (parallel stance closed eyes) of the athletes.

OE and CE nondominant leg postural sway parameters of the athletes and the comparison results between the groups are shown in Table 5. Upon reviewing Table 5, there was an inclination in favor of basketball players regarding the arithmetic means of postural sway in nondominant leg measurements performed with OE and CE. No statistical difference was found between the groups (P>0.05).

Nondominant leg (left) postural sway results of athletes

DISCUSSION

Vestibular problems, which are common in deaf individuals, are known to affect postural control adversely (Stroh et al., 2021). In parallel, the concepts of balance and postural stability are considered among the most significant performance criteria in deaf athletes (Akınoğlu and Kocahan, 2018). The purpose of this study was to examine postural sway values in parallel and single leg stance of Olympic deaf basketball and volleyball players and reveal differences between the branches.

According to the study results, deaf volleyball players were observed to have better results in parallel stance and dominant leg postural sway values than basketball players (P≤0.05) (Tables 3, 4). No difference was identified between branches in nondominant leg postural sway values (Table 5). When the parallel stance and single leg postural sway measurements performed with OE and CE are examined, it is observed that the mean OE values are better in both groups compared to the mean CE values. In parallel with this finding, in their study investigating the effect of hearing loss on physical performance parameters in elite athletes, Akınoğlu and Kocahan (2019b) reported a statistical difference (in favor of OE) between balance performances with OE and CE. This difference in the values of the CE protocol, which was realized in a much more difficult environment than the OE test protocol, seems normal for deaf individuals. In this context, balance and postural stability exercises are recommended, especially for athletes with hearing loss, to prevent performance losses. Akınoğlu and Kocahan (2019b) stated that stabilization and balance training positively affected muscle strength and balance in deaf karate athletes. Zakeri and Taghian (2020) indicated that 8-week resistance and core stability exercises improved the balance ability in deaf children. Furthermore, Zarei et al. (2020) reported that 8-week pilates training positively affected balance performance in female deaf students (age, 16.7±1.7 years). Moreover, proprioceptive intervention programs have been recommended in previous studies for deaf and normal-hearing individuals to maintain postural stability, vestibular function, and balance ability (Cyma-Wejchenig et al., 2020; Majlesi et al., 2014; Martínez-Amat et al., 2013; Wiesmeier et al., 2017). Thus, postural assessment, as well as benefiting from the training methods and practices mentioned above, should be taken into consideration while aiming to reduce the risks of performance loss and possible injury due to balance and postural stability problems of deaf athletes (Sabin et al., 2010). It is also well known that injuries of the lower extremities are common in team sports such as basketball and volleyball (Dallinga et al., 2012).

Considering differences in body stability between deaf and normal-hearing individuals, it is probable that there will be differences between sports branches in deaf athletes. This difference could be caused by learning achieved with respect to the branch after many years, leading to the development of joint proprioception. It is clear that keeping balance and postural stability at an optimum level will positively affect competition performance (Agostini et al., 2013) since side steps, changing direction, and sudden vertical/horizontal jumps are extensively used in basketball and volleyball (Milić et al., 2013). According to the study results, it is an important finding for the literature that deaf volleyball players producehave statistically better results than basketball players in parallel stance and dominant leg postural sway values (Fig. 2). This difference is thought to especially result from the neuromuscular coordination, range of motion, and postural sway tendencies of the volleyball players who participated in the study, depending on the frequency of the actions specific to the sports branch, along with the variables such as a better morphological structure, body composition, and BMI. In the CE dominant leg comparison made in our study, it was revealed that sway path/velocity-based parameters differed in favor of volleyball players. It is assumed that the present finding is related to the effect of the dominant leg on sportive actions in volleyball. Moreover, it has been concluded that there may be an improvement in postural sway along with the improvement in dynamic balance over time since volleyball players are in more contact with the ground (ground reaction force) and constantly perform maneuvers such as spikes/blocks throughout the match. Considering the limited number of studies on the comparison of branches in deaf athletes, factors such as the use of the force plate device with a high validity and reliability in measurements and the sample group consisting of Olympic deaf athletes make the study findings valuable.

According to the results of the study, which examined the postural sway values of deaf basketball and volleyball players and presented the comparison between the branches, it was observed that volleyball players had better results in many postural sway parameters. Especially the difference in the dominant leg values in favor of deaf volleyball players is a significant finding. A possible reason for this may be that long-term practice in volleyball leads to better motor coordination performance and morphological structure. It is also believed that proprioceptive and vestibular system enhancing training practices to be performed with stability exercises (static and dynamic movements) will be beneficial in terms of both promoting functional stability and interlimb coordination. Special training programs (i.e., core stability, pilates) considering differences in the mediolateral, anteroposterior direction and sway velocities revealed in the present study could be useful for preventing possible sport-specific performance losses. Trainers and strength coaches should be aware of differences in the postural control mechanism. Thus, performing periodic postural analyses will be appropriate to determine and prevent the effect of postural abnormalities on body sway, especially in deaf athletes.

The limitations of our study included not having a female group. It is suggested that future researchers could determine if similar results exist in different types of sports. The findings of this study are specific to deaf basketball and volleyball players from our sample group, although all the subjects are at the Olympic level. More research is needed to identify whether our findings can be generalized to all deaf athletes from the same sports.

ACKNOWLEDGMENTS

The authors are very grateful to all the Turkish national deaf men basketball and volleyball players, coaching staff, and managers for their support during the study measurements. The authors received no financial support for this article.

Notes

CONFLICT OF INTEREST

No potential conflict of interest relevant to this article was reported.

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Fig. 1

Representative postural sway diagram from a single study participant during each standing conditions. The postural sway parameters obtained from the Kistler Measurement, Analysis and Reporting Software.

Fig. 2

Statistically significant dominant leg postural sway findings (parallel stance closed eyes) of the athletes.

Table 1

Summary of the outcome postural sway measures, abbreviation, and descriptions

Outcome measure Abbreviation Description
Sway path-time (mm) Sway Path-T The common length of the trajectory of the CoP sway calculated as a sum of the point-to-point Euclidian distances
Sway path-anterior-posterior (mm) Sway Path-AP The common length of the trajectory of the CoP sway only in the anterior-posterior direction.
Sway path-Medial-Lateral (mm) Sway Path-ML The common length of the trajectory of the CoP sway only in the medial-lateral (i.e., left-right) direction.
Sway velocity-time (mm/sec) Sway V-T The common length of the trajectory of the CoP sway calculated as a sum of the point-to-point Euclidian distances divided by the measurement time.
Sway velocity-anterior-posterior (mm/sec) Sway V-AP The common length of the trajectory of the CoP sway only in the anterior-posterior direction divided by the measurement time.
Sway velocity-medial-aateral (mm/sec) Sway V-ML The common length of the trajectory of the CoP sway only in the medial-lateral direction divided by the measurement time.
Sway area-total (mm2) Sway Area-T Area swayed by the CoP trajectory with respect to the central stance point (i.e., mean value of anterior-posterior and medial-lateral components respectively).
Sway area-anterior-posterior (mm/sec) Sway Area-AP The time integral of the anterior-posterior component of the CoP with respect to the mean value of anterior-posterior component.
Sway area-medial-lateral (mm/sec) Sway Area-ML The time integral of the medial-lateral component of the CoP with respect to the mean value of medial-lateral component.
Ellipse area of CoP (mm2) EA-CoP The area of the ellipse fitted over the CoP trajectory so that it contains 100% of all the data points.

CoP, center of pressure.

Table 2

Comparison of demographics variables of the groups

Variable Group No. Mean±SD P-value ES
Age (yr) Basketball 11 25.18±4.57 0.407 0.17
Volleyball 12 24.42±4.42

Height (m) Basketball 11 1.84±0.10 0.720 0.35
Volleyball 12 1.87±0.07

Weight (kg) Basketball 11 83.88±22.01 0.291 0.20
Volleyball 12 80.47±9.44

BMI (kg/m2) Basketball 11 24.55±4.36 0.851 0.40
Volleyball 12 23.08±2.65

Sports years (yr) Basketball 11 6.63±1.63 0.322 0.43
Volleyball 12 7.42±2.03

ES, effect sizes; BMI, body mass index.

Cohen d effect size where 0.2–0.49 is a small effect, 0.5–0.79 is a moderate effect, and ≥0.8 is a large effect.

Table 3

Parallel stance postural sway results of athletes

Parameter Group No. Eyes opened Eyes closed


Mean±SD P-value ES Mean±SD P-value ES
Sway path-time (mm) Basketball 11 162.94±58.27 0.014* 1.67 171.41±84.75 0.718 0.24
Volleyball 12 90.73±17.52 208.41±200.15

Sway path-anterior-posterior (mm) Basketball 11 101.44±47.99 0.199 0.40 132.86±67.60 0.907 0.07
Volleyball 12 81.57±50.28 128.49±57.53

Sway path-medial-lateral (mm) Basketball 11 66.64±27.15 0.026* 1.03 80.09±43.65 0.916 0.19
Volleyball 12 44.89±11.92 72.91±30.40

Sway velocity-time (mm/sec) Basketball 11 16.30±10.03 0.020* 0.99 17.14±8.47 0.509 0.36
Volleyball 12 9.32±2.10 14.47±5.95

Sway velocity-anterior-posterior (mm/sec) Basketball 11 10.14±4.80 0.008** 1.10 13.29±6.76 0.907 0.07
Volleyball 12 6.40±1.14 12.85±5.75

Sway velocity-medial-lateral (mm/sec) Basketball 11 7.17±2.68 0.005** 1.35 8.15±4.34 0.675 0.34
Volleyball 12 4.37±1.03 6.91±2.70

Sway area-total (mm2) Basketball 11 132.64±77.76 0.410 0.44 174.99±107.11 0.601 0.14
Volleyball 12 103.70±49.20 189.76±104.65

Sway Area-Anterior-Posterior (mm/sec) Basketball 11 53.04±23.23 0.148 0.68 47.41±24.04 0.607 0.11
Volleyball 12 39.19±16.78 49.73±17.77

Sway area-medial-lateral (mm/sec) Basketball 11 16.79±7.05 0.038* 0.78 18.39±8.67 0.214 0.64
Volleyball 12 11.22±6.68 13.82±5.21

Ellipse area (mm2) Basketball 11 39.55±25.59 0.011* 1.23 40.51±27.27 0.568 0.42
Volleyball 12 15.74±8.43 30.61±18.80

ES, effect sizes.

Cohen d effect size where 0.2–0.49 is a small effect, 0.5–0.79 is a moderate effect, and ≥0.8 is a large effect.

*

P<0.05.

**

P<0.01.

Table 4

Dominant leg (right) postural sway results of athletes

Parameter Group No. Eyes opened Eyes closed


Mean±SD P-value ES Mean±SD P-value ES
Sway path-time (mm) Basketball 11 565.95±167.87 0.619 0.21 2,033.55±536.77 0.001*** 1.59
Volleyball 12 530.05±173.58 1,337.23±302.34

Sway path-anterior-posterior (mm) Basketball 11 340.94±81.35 0.241 0.46 1,421.10±652.68 0.037* 0.88
Volleyball 12 301.73±85.96 956.08±366.47

Sway path-medial-lateral (mm) Basketball 11 386.05±143.18 0.973 0.06 1,072.16±224.98 0.375 0.26
Volleyball 12 377.39±135.24 998.44±371.28

Sway velocity-time (mm/sec) Basketball 11 56.60±16.79 0.568 0.23 203.36±53.69 0.048* 0.77
Volleyball 12 52.57±17.45 160.22±58.55

Sway velocity-anterior-posterior (mm/sec) Basketball 11 34.10±8.14 0.325 0.38 142.12±65.27 0.028* 0.90
Volleyball 12 30.80±8.88 93.70±40.26

Sway velocity-medial-lateral (mm/sec) Basketball 11 38.61±14.32 0.900 0.02 107.22±22.49 0.800 0.13
Volleyball 12 38.96±14.52 114.02±66.33

Sway area-total (mm2) Basketball 11 2,339.06±1,400.66 0.860 0.03 28,421.36±13,441.75 0.210 0.53
Volleyball 12 2,291.42±1,104.53 21,783.92±11,102.12

Sway Area-Anterior-Posterior (mm/sec) Basketball 11 86.38±39.80 0.907 0.03 229.10±80.82 0.993 0.01
Volleyball 12 87.71±40.41 228.23±81.69

Sway area-medial-lateral (mm/sec) Basketball 11 71.08±24.03 0.554 0.33 314.56±146.84 0.660 0.01
Volleyball 12 64.42±15.33 313.58±183.10

Ellipse area (mm2) Basketball 11 275.44±149.64 0.317 0.54 3,659.55±2,101.13 0.471 0.24
Volleyball 12 209.31±84.30 3,167.82±1,988.61

ES, effect sizes.

Cohen d effect size where 0.2–0.49 is a small effect, 0.5–0.79 is a moderate effect, and ≥0.8 is a large effect.

*

P<0.05.

***

P<0.001.

Table 5

Nondominant leg (left) postural sway results of athletes

Parameter Group No. Eyes opened Eyes closed


Mean±SD P-value ES Mean±SD P-value ES
Sway path-time (mm) Basketball 11 693.16±246.55 0.576 0.24 1,760.45±611.61 0.404 0.38
Volleyball 12 756.91±278.56 2,031.27±801.61

Sway path-anterior-posterior (mm) Basketball 11 400.94±124.15 0.726 0.09 1,189.42±466.49 0.714 0.24
Volleyball 12 411.58±101.51 1,347.48±814.12

Sway path-medial-lateral (mm) Basketball 11 493.52±207.81 0.697 0.16 1,003.12±362.01 0.378 0.32
Volleyball 12 531.73±268.10 1,115.13±332.93

Sway velocity-time (mm/sec) Basketball 11 76.33±34.54 0.869 0.09 1,76.05±61.16 0.404 0.38
Volleyball 12 80.41±50.75 203.14±80.17

Sway velocity-anterior-posterior (mm/sec) Basketball 11 42.28±15.80 0.713 0.28 118.95±46.65 0.714 0.24
Volleyball 12 38.55±9.50 134.77±81.42

Sway velocity-medial-lateral (mm/sec) Basketball 11 52.40±24.73 0.942 0.19 100.31±36.20 0.378 0.32
Volleyball 12 48.43±15.89 111.53±33.30

Sway area-total (mm2) Basketball 11 3,793.55±2,125.78 0.193 2.29 22,558.55±13,298.36 0.217 0.50
Volleyball 12 9,899.75±3,111.73 32,286.33±24,200.26

Sway Area-Anterior-Posterior (mm/sec) Basketball 11 96.46±33.80 0.178 0.67 229.29±97.41 0.533 0.15
Volleyball 12 136.01±75.34 243.71±89.17

Sway area-medial-lateral (mm/sec) Basketball 11 106.02±58.51 0.597 0.24 229.19±94.09 0.058 1.02
Volleyball 12 124.46±91.79 336.02±113.96

Ellipse area (mm2) Basketball 11 378.10±255.82 0.122 0.49 4,120.36±1,806.32 0.784 0.23
Volleyball 12 484.85±175.01 4,585.91±2,158.60

ES, effect sizes.

Cohen d effect size where 0.2–0.49 is a small effect, 0.5–0.79 is a moderate effect, and ≥0.8 is a large effect.