- 1Sports Medical Research Group, Department of Orthopaedics, Balgrist University Hospital, University of Zurich, Zurich, Switzerland
- 2University Centre for Prevention and Sports Medicine, Department of Orthopaedics, Balgrist University Hospital, University of Zurich, Zurich, Switzerland
- 3Swiss Council for Accident Prevention BFU, Bern, Switzerland
- 4Department of Sport, Exercise and Health, University of Basel, Basel, Switzerland
- 5FC Basel 1893, Basel, Switzerland
- 6Institute of Physiology, Department of Biomedical Sciences, University of Padova, Padova, Italy
From a preventative perspective, leg axis and core stabilization capacities are important for soccer players and alpine skiers; however, due to different sport-specific demands, the role of laterality clearly differs and may result in functional long-term adaptations. The aims of this study are 1) to determine whether there are differences in leg axis and core stability between youth soccer players and alpine skiers and 2) between dominant and non-dominant sides, and 3) to explore the outcomes of applying common sport-specific asymmetry thresholds to these two distinct cohorts. Twenty-one highly trained/national-level soccer players (16.1 years, 95% CI: 15.6, 16.5) and 61 alpine skiers (15.7 years, 95% CI: 15.6, 15.8) participated in this study. Using a marker-based 3D motion capture system, dynamic knee valgus was quantified as the medial knee displacement (MKD) during drop jump landings, and core stability was quantified as the vertical displacement during deadbug bridging exercise (DBBdisplacement). For the analysis of sports and side differences, a repeated-measures multivariate analysis of variance was used. For the interpretation of laterality, coefficients of variation (CV) and common asymmetry thresholds were applied. There were no differences in MKD or DBBdisplacement between soccer players and skiers or between the dominant and non-dominant sides, but there was an interaction effect side*sports for both variables (MKD: p = 0.040, η2p = 0.052; DBBdisplacement: p = 0.025, η2p = 0.061). On average, MKD was larger on the non-dominant side and DBBdisplacement laterality on the dominant side in soccer players, whereas this pattern was reversed in alpine skiers. Despite similar absolute values and asymmetry magnitudes of dynamic knee valgus and deadbug bridging performance in youth soccer players and alpine skiers, the effect on the direction of laterality was opposite even though much less pronounced. This may imply that sport-specific demands and potential laterality advantages should be considered when dealing with asymmetries in athletes.
1 Introduction
Humans typically prefer one side for the execution of motor tasks, hence resulting in a more skilled side, often called laterality or side dominance (Carpes et al., 2010; Maloney, 2019; Hart et al., 2020; Westin et al., 2022b). In this context, laterality describes a difference in body morphology or function (Hart et al., 2020). Several sports-related motor tasks, such as throwing or kicking, are strongly related to unilateral execution, thus manifesting in a high degree of laterality as a consequence of functional long-term adaptations (Newton et al., 2006; Parrington and Ball, 2016; Bishop et al., 2018b; Lijewski et al., 2021), while others are more symmetrical with less pronounced, but still present, laterality (e.g., running, cycling, or swimming) (Parrington and Ball, 2016; Maloney, 2019). One sport with high laterality is soccer, a globally popular team sport where physical, tactical, and technical components are crucial for team success (Stolen et al., 2005). In terms of physical demands, well-performed changes of direction are the key and have been described as the best discriminant variable among young players regarding selection into superior teams (Gil et al., 2007a; Gil M. et al., 2007b). Although fast changes of direction in soccer are made as a reaction to game situations and, therefore, are multidirectional, the dominant leg can usually perform faster change of direction maneuvers than the non-dominant leg (Rouissi et al., 2016). Another central aspect in soccer is kicking, with players favoring one limb, which is referred to as the dominant limb (DeLang et al., 2019). In total, more than 80% of the ball contacts are performed with the dominant leg (Carey et al., 2001). Hence, soccer activity is strongly characterized by the asymmetrical nature of the sport. By contrast, for athletes from alpine skiing, i.e., a more symmetric sport, less laterality can be expected. Alpine skiing places high loads on the athletes’ bodies, forces up to 1.75 times their body weight on each leg (Kröll et al., 2016), combined with high knee flexion angles and valgus (Zorko et al., 2015), and enormous force and stabilization capacity are required. The interaction with snow causes vibration loads and impact-like shocks that are largely absorbed by the knee and its stabilizing muscles (Spörri et al., 2017; Supej et al., 2018). When compared to soccer, however, the physical demands are more symmetric, and thus, side dominance may play a subordinate role. Such different demands are likely to result in functional long-term adaptations that have to be considered when dealing with asymmetries in athletes.
Injuries are common in soccer players (Eirale et al., 2013; Hagglund et al., 2013). Anterior cruciate ligament (ACL) injury incidences are high (0.06–3.7 per 1,000 h of training and competition) (Bjordal et al., 1997; Fauno and Wulff Jakobsen, 2006) and predominantly occur without player-to-player contact; hence, ACL injuries are referred to as non-contact injuries (Fauno and Wulff Jakobsen, 2006; Alentorn-Geli et al., 2009). Interestingly, the dominant leg, when compared to the non-dominant leg, is commonly associated with a decreased knee flexor (i.e., hamstrings) to knee extensor (i.e., quadriceps) strength ratio (Rahnama et al., 2005) and is more frequently subjected to injuries (DeLang et al., 2021). Typical situational patterns leading to ACL injuries are indirect or non-contact situations, such as pressing/tackling, regaining balance after kicking, landing from a jump, and being approached (Della Villa et al., 2020). In this regard, the following movements are at high risk: cutting maneuvers combined with deceleration, near- or fully extended jump landings, and pivoting with an extended knee and a planted foot (Boden et al., 2000; Fauno and Wulff Jakobsen, 2006). Similarly, alpine skiers are also at high risk of sustaining knee injuries (Florenes et al., 2009; Florenes et al., 2012), whereas ACL rupture represents the most frequent diagnosis (Florenes et al., 2009). ACL injuries almost exclusively occur while skiing; they are only rarely caused by a crash (Bere et al., 2011). In this regard, the following three main injury mechanisms are defined and described in detail elsewhere: slip-catch, landing back-weighted, and dynamic snowplow (Bere et al., 2011). In brief, when turning, the skier gets out of balance before the sudden edge catch of the outside ski forcing the knee into valgus and internal rotation (slip–catch mechanism) (Bere et al., 2011). Back-weighted jump landing results from losing balance during flight and then trying to recover, when a combination of tibiofemoral compression and anterior drawer of the tibia in relation to the femur acts on the athlete’s knee (Meyer and Haut, 2008; Bere et al., 2011). Dynamic snowplowing starts in a back-weighted out-of-balance situation, leading to a split position and unloaded outer ski, and the loaded ski grips on the inner edge, subsequently leading to internal rotation and valgus (Bere et al., 2011).
Considering the aforementioned sport-specific mechanisms of ACL injuries and concomitant lesions, it is reasonable to consider poor leg axis stability (i.e., extensive dynamic knee valgus) a modifiable risk factor (Hewett et al., 2006) that plays a key role in injury mechanisms (Bere et al., 2011). Medial knee displacement (MKD) can be reliably quantified during drop jump (DJ) landing (Paterno et al., 2010; Krosshaug et al., 2016; Leppanen et al., 2016; Ellenberger et al., 2020b). Furthermore, core stability may be preventative in the context of out-of-balance mechanisms in ACL injuries (Hewett et al., 2005; Zazulak et al., 2007). However, an objective, reliable, and valid quantification of core stability is challenging (Hibbs et al., 2008). A more holistic approach that has been proven to be suitable in the context of injury prevention is the quantification of the rear chain stabilization capacity (Ellenberger et al., 2020a). In this regard, the anti-torsional stabilization capacity is assessed through the hip axis tilt in the frontal plane during deadbug bridging (DBBdisplacement) (Ellenberger et al., 2020a). Both the MKD during DJ landings and DBBdisplacement are preferably quantified with a motion capture system, such as the Vicon Nexus.
To what extent does high degrees of laterality influence athletic performance and the risk of injury in different sports has not yet been conclusively clarified (Knapik et al., 1991; Bourne et al., 2015; Bishop et al., 2018b; Dos'Santos et al., 2019; Maloney, 2019; Bishop et al., 2022; Westin et al., 2022a). Traditionally, subjects with interlimb asymmetries of >10%–15% have been associated with higher injury incidences than those with such asymmetries below this threshold (Barber et al., 1990; Impellizzeri et al., 2007; Grindem et al., 2011). However, it is not a priori clear whether, especially in highly asymmetrical sports, a high degree of laterality is adverse and must be prevented or whether, on the contrary, it is actually the key in enhancing performance or protecting athletes. Accordingly, recent research have proposed a more sophisticated approach for laterality analysis, which include cohort- and task-specific thresholds to account for the task- and metric-dependent nature of asymmetries (Bishop et al., 2018a; Bishop et al., 2021; Dos’Santos et al., 2021). Moreover, Exell et al. (2012) have stated that the asymmetry percentage must be larger than the coefficient of variation and suggested the application of an individual approach in the context of interlimb asymmetry considerations.
Accordingly, the aims of this study were threefold: 1) to determine whether there are distinct differences in leg axis and core stability between soccer players and skiers, 2) to investigate whether youth soccer players and alpine skiers exhibit leg axis and core stability differences between the dominant and non-dominant sides, and 3) to explore the outcomes of applying common sport-specific asymmetry thresholds to these two distinct cohorts. Considering the literature and the great importance of core and leg axis stability in both alpine skiing and soccer, similar absolute values have been hypothesized for both cohorts in their respective exercise tests. However, due to the asymmetric nature of the demands in soccer, which are in contrast to alpine skiing, it was been hypothesized that there would be greater differences between the dominant and non-dominant sides than it is for alpine skiers. Accordingly, a higher percentage of individuals in the soccer cohort were expected to be classified as asymmetric.
2 Materials and methods
2.1 Participants and study design
Twenty-one male youth soccer players and 61 youth alpine skiers participated in a cross-sectional study and were assessed with respect to leg axis and core stability as further defined below. All data were collected at a single point in time [i.e., before the competitive season in October (alpine skiers) and in January (soccer players)] and were analyzed without any interventional influence. Data collection took place on dedicated test days directly at the athletes’ training facilities using a standardized mobile measurement setup and operated by the same experienced team of evaluators. Standard pretest preparation advice included no intense training or competition 24 h prior to testing and only healthy athletes participated.
Alpine skiers were recruited through their membership in a youth development structure of a national skiing association. The recruitment of the soccer players was based on their membership in a professional youth soccer academy and playing in the corresponding U16–U18 teams. Regarding training and performance classification, both cohorts met the criteria for Tier 3, which is defined as highly trained and competing at the national level (McKay et al., 2022). Further eligibility criteria were not being in a back-to-sports program after injury and not having systematic pathologies, diabetes mellitus, or inflammatory arthritis. The resulting sample size represents the full availability of healthy athletes within the cooperating associations at the time of assessment.
The selection of the two sports investigated was based, as outlined in the introduction, on the idea of comparing a group with highly symmetrical sport-specific requirements with a group that particularly has asymmetrical requirements. Alpine skiing and soccer are the two sports that fulfil this criterion and are also of high interest for injury prevention research due to their high risks.
All participants/participants’ legal guardian/next of kin were informed about the study and provided written informed consent. The corresponding study protocols were approved by the local ethics committees (KEK-ZH-NR: 2017-01395 and EKNZ 2017-02148), and the procedures were in full accordance with the Declaration of Helsinki and national laws.
2.2 Data collection
Leg axis stability was quantified as medial knee displacement (MKD; in mm) during drop jump (DJ) landings (Ellenberger et al., 2020b). The MKD was specified as the maximal distance between the knee joint center during the ground contact phase and the predefined reference plane. The reference plane consisted of the hip, knee joint center, and ankle joint center and was set to one frame before ground contact. A threshold of 25 N was used to determine ground contact for both legs independently. The subjects were instructed to drop off from a 32-cm-high box in upright posture and subsequently perform a maximum height vertical jump with minimal ground contact time. Throughout the trial, both hands had to remain on the pelvis, and the subjects had to land with their feet on two adjacent force plates. A trial was considered invalid if the participants i) actively jumped off the box, ii) lost hand contact with the pelvis, iii) did not correctly hit the force plates, or iv) had hesitation in jumping off after landing. The subjects were asked to perform additional trials until two valid trials were recorded, with a minimum of 15 s of recovery time between the trials.
Core stability was quantified as the maximum amplitude of the vertical displacement (in mm) of the two pelvis markers during deadbug bridging exercise, with the marker of the stabilizing side representing the reference marker (DBBdisplacement), as suggested previously (Ellenberger et al., 2020a). Thus, DBBdisplacement of the dominant side represents the displacement with the dominant side stabilizing while the non-dominant leg is lifted, and vice versa. In this regard, the subjects were asked to take a supine position on the floor with their arms abducted 90° from the body and their palms facing upward. Leg abduction was oriented such that the heels were in line with the elbows. To reach the starting position, the athletes were asked to lift their hip and keep ground contact only with their heels and shoulders. Subsequently, one heel had to be lifted to a position with knee and hip flexion angles of 90°. Holding this position for 3 s and returning to the starting position was one repetition. One trial consisted of three consecutive repetitions, without the hip touching the ground in between. The trial was repeated if i) the system could not detect the markers properly due to hip flexion, ii) the starting position was not taken properly, or iii) the hip touched the ground.
Biomechanical assessments were recorded with an optoelectronic 3D motion capture system with eight cameras (Vicon, Oxford Metrics) operating at 200 Hz. Additionally, two force plates were included in and synchronized with the measurement setup (SP Sportdiagnosegeräte GmbH) operating at 2,000 Hz. Participants were equipped with 31 reflective skin markers for DJ assessment, and placement was performed as defined by (Ellenberger et al., 2020b) in a slightly modified form of the plug-in-gait model (Vicon Nexus v2.6, Oxford Metrics). Prior to the dynamic assessment, four additional markers were placed on the medial femur epicondyles and the medial malleoli on both legs, and a static calibration was performed, allowing a more precise determination of knee and ankle joint centers. For the deadbug bridging performance assessments, four markers were bilaterally placed on the anterior superior iliac spine and the lateral malleoli. For both groups, the dominant leg was defined as the preferred leg to perform a soccer kick. All assessments were performed barefoot.
2.3 Data evaluation
Marker trajectories were identified using the Vicon Nexus software (Vicon Nexus v2.6, Oxford Metrics). Subsequently, the data were transferred to MATLAB (MATLAB R2016b, MathWorks, Inc.), and a customized MATLAB script was used for post-processing and parameter calculation. Interpolation of gaps in the marker trajectory was performed for a maximum of 10 frames (0.05 s). For DJ data processing, the reference plane was set one frame before ground contact for each leg separately and remained fixed at the hip joint center throughout the contact phase. The rectangular distance between the reference plane and the knee joint center throughout the trial was considered in MKD [mm]. Deadbug bridging trials were cut into three repetitions, identified through the minimal vertical height of the lateral malleolus marker of the lifted leg. For the three repetitions, the maximal amplitude in millimeters of the vertical displacement of the anterior superior iliac spine markers was averaged and then considered DBBdisplacement, with the height of the stabilizing side as the reference. Such protocols for assessing MKD and DBBdisplacement have been shown to be reliable in previous studies (Ellenberger et al., 2020a; Ellenberger et al., 2020b). Individual laterality assessments were performed following the suggestions of Impellizzeri et al. (2007); asymmetry was thus calculated as the difference between the larger and smaller values divided by the larger value and represented in percent (Impellizzeri et al., 2007). To make visible which side had larger displacement, all asymmetry values where the non-dominant side represented the larger displacement value were multiplied by −1.
2.4 Statistical analysis
The IBM SPSS statistics software version 28 was used for statistical analysis. The assumption of normality was checked for all metric data using the Shapiro‒Wilk test. All baseline characteristics are expressed as the group mean with 95% confidence interval in brackets. Repeated-measures multivariate analysis of variance (MANOVA) with Bonferroni correction for pairwise comparisons was used for the analysis of potential MKD and DBBdisplacement differences. The within-subject factor was the side (dominant vs. non-dominant), and the between-subject factor was sports (soccer vs. alpine skiing). For the interpretation of laterality, coefficients of variation (CVs) and common asymmetry thresholds were used (Impellizzeri et al., 2007; Exell et al., 2012; Bishop et al., 2018a; Dos’Santos et al., 2021). In brief, the CV was calculated for each subject and exercised individually as a measure of reliability, and asymmetry thresholds were calculated for both cohorts and exercises as the classification criteria for the distinctiveness of laterality. Small to moderate asymmetry was assumed when athletes were above a threshold calculated as population mean + smallest worthwhile change (SWC; defined as 0.2 * SD between subjects) (Dos’Santos et al., 2021). The high asymmetry threshold was defined as laterality differences above the population mean + SD (Dos’Santos et al., 2021).
3 Results
3.1 Baseline characteristics
The baseline characteristics for all participating soccer players and alpine skiers, such as age, body height, and body weight, are presented in Table 1.
3.2 Repeated-measures multivariate analysis of variance
On a multivariate level, there were no significant differences between the sports (soccer player vs. skiers; p = 0.459, η2p = 0.020) and the side (dominant vs. non-dominant; p = 0.107, η2p = 0.055), but there was an interaction effect side*sports (p = 0.014, η2p = 0.102). As presented in Figures 1A, B, univariate tests did not reveal any significant differences in MKD (p = 0.345, η2p = 0.011) or DBBdisplacement (p = 0.398, η2p = 0.009) between the sports or between sides (MKD: p = 0.244, η2p = 0.017; DBBdisplacement: p = 0.065, η2p = 0.042), but an interaction effect side*sports was observed for both variables (MKD: p = 0.040, η2p = 0.052; DBBdisplacement: p = 0.025, η2p = 0.061) (Table 2).
FIGURE 1. (A,B) Diagram with population mean, 95% CI, and individual values for deadbug bridging (DBB) and medial knee displacement (MKD). (A) Profile diagram for the interaction effect side*sports with respect to the maximum amplitude of the vertical displacement of the two pelvis markers during DBB exercise, with the marker of the stabilizing side representing the reference marker (DBBdisplacement). (B) Profile diagram for the interaction effect side*sports withrespect to MKD.
TABLE 2. Medial knee displacement (MKD) and deadbug bridging displacement (DBB) for soccer players and alpine skiers.
A detailed overview of the MKD and DBBdisplacement values for each side and sport is given in Figure 1. On average, MKD laterality was directed to the non-dominant side and DBBdisplacement laterality to the dominant side in soccer players, whereas this pattern was reversed in alpine skiers, even though it was much less pronounced. Thus, despite similar absolute values and asymmetry magnitudes of dynamic knee valgus and deadbug bridging performance in youth soccer players and alpine skiers, the effect on the direction of laterality was opposite.
3.3 CV values and derivation of sport-specific asymmetry thresholds
Overall, the asymmetry CV values observed were relatively high: 0.1%–178.3% and 2.2%–94.2% for MKD and DBBdisplacement, respectively. The sport-specific small to moderate and high asymmetry thresholds for MKD were 48.28% and 66.44% for soccer players (Figure 2B) and 45.10% and 65.25% for the skier group, respectively (Figure 2A). Small to moderate MKD asymmetries were detected in three soccer players (14.3%) and eight skiers (13.1%). High asymmetry values regarding MKD were found only in one soccer player (i.e., 4.8%) and in five skiers (i.e., 8.2%). For DBBdisplacement, the sport-specific thresholds for small to moderate and high asymmetries were 21.0% and 34.3% for soccer players (Figure 3B) and 20.8% and 29.6% for skiers (Figure 3A), respectively. One soccer player (i.e., 4.8%) and seven skiers (i.e., 11.5%) had small to moderate asymmetries, and three soccer players (i.e., 14.3%) and six skiers (i.e., 9.8%) had high asymmetries.
FIGURE 2. (A,B) Individual medial knee displacement (MKD) asymmetry data (bars) with the respective coefficient of variation (blue bullet points), threshold for small to moderate asymmetry [population mean + smallest worthwhile change (SWC), dashed lines], and threshold for high asymmetry (population mean + SD, dotted lines). (A) Alpine skiers; (B) soccer players.
FIGURE 3. (A,B) Individual deadbug bridging displacement (DBBdisplacement) asymmetry data (bars) with respective coefficients of variation (blue bullet points), thresholds for small to moderate asymmetry [population mean + smallest worthwhile change (SWC), dashed lines], and thresholds for high asymmetry (population mean + SD, dotted lines). (A) Alpine skiers; (B) soccer players.
4 Discussion
4.1 Similar absolute values and asymmetry magnitudes of dynamic knee valgus and deadbug bridging performance in youth soccer players and alpine skiers
Overall, the current study revealed no significant differences in MKD and DBBdisplacement between soccer players and skiers or between their dominant and non-dominant sides, underpinning the comparability of the two distinct cohorts examined in terms of their absolute values and asymmetry magnitudes of dynamic knee valgus and deadbug bridging performance. This is, on the one hand, certainly surprising, as soccer is, when compared to alpine skiing, a sport of a rather asymmetric nature (Rouissi et al., 2016; Bishop et al., 2021). However, on the other hand, a previous study in alpine skiing has reported a clear side dominance in the occurrence of ACL injuries (Westin et al., 2018), which is why the presence of lateralities in terms of functional performance factors also appears quite plausible. A potential relationship between these factors has been demonstrated, for example, for side-to-side differences in the side hop test and knee joint laxity, which have been shown to be factors that predispose skiers to ACL re-injury (Westin et al., 2022a).
4.2 Opposite laterality directions in soccer players compared with alpine skiers and their implications for dealing with asymmetric athletes
Despite a lack of main effects, the MANOVA revealed a crossover interaction between side* and sports for both MKD and DBBdisplacement. This means that there is a distinct effect of the specific sport on comparisons between the dominant and non-dominant sides.
In soccer players, MKD laterality was directed to the non-dominant side and DBBdisplacement laterality to the dominant side, whereas this pattern was reversed in alpine skiers, even though it was much less pronounced. For soccer players, this implies that while DJ landing the non-dominant leg (i.e., the standing leg) expressed higher magnitudes of dynamic knee valgus than the dominant leg (i.e., the kicking leg), and during the execution of the deadbug bridging exercise, the dominant side (i.e., the side ipsilateral to the kicking leg) had poorer stabilization performance than the contralateral side. From a functional perspective, such laterality makes absolute sense, since during cutting maneuvers, high dynamic valgus loads are evoked (McLean et al., 1998; Besier et al., 2001) and soccer players can typically perform faster cutting with the dominant leg (Rouissi et al., 2016). Thus, the dominant leg is the one that has to sustain the highest valgus stress and is therefore plausible to develop higher leg axis stability over time. This also reflects muscle strength assessments, where knee flexors and extensors of the dominant leg shows superior strength capacity when compared to the non-dominant leg (Rouissi et al., 2016; Rouissi et al., 2018). Moreover, higher strength in valgus antagonistic hip abductor muscles (i.e., M. gluteus medius and minimus) was found for the dominant legs of soccer players than for the non-dominant leg (Rouissi et al., 2016; Rouissi et al., 2018). Then, while kicking, when similarly executing a deadbug bridging exercise, the dominant side (i.e., the side ipsilateral to the kicking leg) rotates around the non-dominant side (with the fixed standing leg) (Kellis and Katis, 2007; Lees et al., 2010). The corresponding rotational acceleration of the pelvis on the dominant side by the diagonal concentric activation of the obliquus internus abdominis and obliquus externus abdominis muscles represents the same activation pattern as eccentrically breaking the hip axis drop on the non-dominant side with the punctum fixum on the dominant side. Accordingly, the finding of a better deadbug bridging stabilization performance on the non-dominant side is also a plausible functional adaptation to typical loading patterns in soccer.
By contrast, MKD in alpine skiers again shows less pronounced but oppositely directed laterality. This may represent a slightly more symmetric stabilization capacity but with slightly higher medial displacement within the dominant leg. Likewise, DBBdisplacement laterality was smaller than that in soccer players and oppositely directed to the non-dominant side. Another interesting observation, however, is the observation that at the individual level, a slightly higher percentage of alpine skiers were classified as asymmetric when compared to soccer players. This may be explained by the slightly lower professionalization of youth development programs at the U16 level in alpine skiing and lower financial resources that can be invested in systematically testing and addressing functional asymmetries, a difference that gradually disappears at higher levels.
In summary, despite similar absolute values and asymmetry magnitudes of dynamic knee valgus and deadbug bridging performance in youth soccer players and alpine skiers, the effect on the direction of laterality was opposite. It appears that sport-specific demands influence the direction rather than the presence and magnitude of asymmetries.
4.3 Study limitations
The first limitation of this study is that the coefficient of variance calculations for the MKD measures consisted of only two measurements, potentially limiting the representativeness for the corresponding asymmetry threshold derivation. Worth noting in this context are the rather large within-subject CV values observed in the current study. To some degree, this might be favored by the highly dynamic nature of the assessed movement tasks and also by the limited number of measurement repetitions underlying these calculations. The second limitation is differences in the number of participants within the groups, which was caused by the availability of the corresponding athletes.
5 Conclusion
As shown in this study, a certain degree of laterality is present in both youth soccer players and alpine skiers, and this is of a similar magnitude. However, despite similar absolute values and asymmetry magnitudes of dynamic knee valgus and deadbug bridging performance in youth soccer players and alpine skiers, the effect on the direction of laterality was opposite. This implies that the corresponding sports had a significant impact on the comparison between the dominant and non-dominant sides. Accordingly, our results underline the evident need to analyze lateralities on the basis of sport- or population-specific thresholds. Depending on the sport, laterality is not “unfavorable” per se, and potential functional advantages and disadvantages should be considered when addressing individual asymmetries in athletes.
Data availability statement
The datasets presented in this article are not readily available because their access is restricted to protect the interests of the project partner FC Basel and Swiss-Ski and their athletes. Requests to access the datasets should be directed to am9lcmcuc3BvZXJyaUBiYWxncmlzdC5jaA==.
Ethics statement
The studies involving human participants were reviewed and approved by KEK-ZH-NR: 2017-01395 EKNZ 2017-02148. Written informed consent to participate in this study was provided by the participants/participants’ legal guardian/next of kin.
Author contributions
JS and OF conceptualized and designed the study, recruited the participants, and organized the data collection. JS and LE collected the data. JH and LE processed the data and performed the statistical analysis. JH and JS interpreted the data and drafted the current manuscript, and all authors revised it critically and approved the final version of the manuscript.
Funding
This study was generously supported by the Balgrist Foundation, Swiss-Ski, the “Stiftung Passion Schneesport” and the “Stiftung zur Förderung des alpinen Skisportes in der Schweiz.” We would like to thank all participants, parents, and coaches involved.
Conflict of interest
The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.
Publisher’s note
All claims expressed in this article are solely those of the authors and do not necessarily represent those of their affiliated organizations, or those of the publisher, editors, and reviewers. Any product that may be evaluated in this article, or claim that may be made by its manufacturer, is not guaranteed or endorsed by the publisher.
References
Alentorn-Geli, E., Myer, G. D., Silvers, H. J., Samitier, G., Romero, D., Lazaro-Haro, C., et al. (2009). Prevention of non-contact anterior cruciate ligament injuries in soccer players. Part 1: Mechanisms of injury and underlying risk factors. Knee Surg. Sports Traumatol. Arthrosc. 17, 705–729. doi:10.1007/s00167-009-0813-1
Barber, S. D., Noyes, F. R., Mangine, R. E., Mccloskey, J. W., and Hartman, W. (1990). Quantitative assessment of functional limitations in normal and anterior cruciate ligament-deficient knees. Clin. Orthop. Relat. Res., 255, 204–214. doi:10.1097/00003086-199006000-00028
Bere, T., Florenes, T. W., Krosshaug, T., Koga, H., Nordsletten, L., Irving, C., et al. (2011). Mechanisms of anterior cruciate ligament injury in world cup alpine skiing: A systematic video analysis of 20 cases. Am. J. Sports Med. 39, 1421–1429. doi:10.1177/0363546511405147
Besier, T. F., Lloyd, D. G., Cochrane, J. L., and Ackland, T. R. (2001). External loading of the knee joint during running and cutting maneuvers. Med. Sci. Sports Exerc 33, 1168–1175. doi:10.1097/00005768-200107000-00014
Bishop, C., Abbott, W., Brashill, C., Turner, A., Lake, J., and Read, P. (2022). Bilateral vs. Unilateral countermovement jumps: Comparing the magnitude and direction of asymmetry in elite academy soccer players. J. Strength Cond. Res. 36, 1660–1666. doi:10.1519/JSC.0000000000003679
Bishop, C., Lake, J., Loturco, I., Papadopoulos, K., Turner, A., and Read, P. (2021). Interlimb asymmetries: The need for an individual approach to data analysis. J. Strength Cond. Res. 35, 695–701. doi:10.1519/JSC.0000000000002729
Bishop, C., Read, P., Lake, J., Chavda, S., and Turner, A. (2018a). Interlimb asymmetries: Understanding how to calculate differences from bilateral and unilateral tests. Strength & Cond. J. 40, 1–6. doi:10.1519/ssc.0000000000000371
Bishop, C., Turner, A., and Read, P. (2018b). Effects of inter-limb asymmetries on physical and sports performance: A systematic review. J. Sports Sci. 36, 1135–1144. doi:10.1080/02640414.2017.1361894
Bjordal, J. M., Arnly, F., Hannestad, B., and Strand, T. (1997). Epidemiology of anterior cruciate ligament injuries in soccer. Am. J. Sports Med. 25, 341–345. doi:10.1177/036354659702500312
Boden, B. P., Dean, G. S., Feagin, J. A., and Garrett, W. E. (2000). Mechanisms of anterior cruciate ligament injury. Orthopedics 23, 573–578. doi:10.3928/0147-7447-20000601-15
Bourne, M. N., Opar, D. A., Williams, M. D., and Shield, A. J. (2015). Eccentric knee flexor strength and risk of hamstring injuries in rugby union: A prospective study. Am. J. Sports Med. 43, 2663–2670. doi:10.1177/0363546515599633
Carey, D. P., Smith, G., Smith, D. T., Shepherd, J. W., Skriver, J., Ord, L., et al. (2001). Footedness in world soccer: An analysis of France '98. J. Sports Sci. 19, 855–864. doi:10.1080/026404101753113804
Carpes, F. P., Mota, C. B., and Faria, I. E. (2010). On the bilateral asymmetry during running and cycling - a review considering leg preference. Phys. Ther. Sport 11, 136–142. doi:10.1016/j.ptsp.2010.06.005
Delang, M. D., Rouissi, M., Bragazzi, N. L., Chamari, K., and Salamh, P. A. (2019). Soccer footedness and between-limbs muscle strength: Systematic review and meta-analysis. Int. J. Sports Physiol. Perform. 14, 551–562. doi:10.1123/ijspp.2018-0336
Delang, M. D., Salamh, P. A., Farooq, A., Tabben, M., Whiteley, R., Van Dyk, N., et al. (2021). The dominant leg is more likely to get injured in soccer players: Systematic review and meta-analysis. Biol. Sport 38, 397–435. doi:10.5114/biolsport.2021.100265
Della Villa, F., Buckthorpe, M., Grassi, A., Nabiuzzi, A., Tosarelli, F., Zaffagnini, S., et al. (2020). Infographic. Systematic video analysis of ACL injuries in professional male football (soccer): Injury mechanisms, situational patterns and biomechanics study on 134 consecutive cases. Br. J. Sports Med. 55, 405–406. doi:10.1136/bjsports-2020-103241
Dos'santos, T., Bishop, C., Thomas, C., Comfort, P., and Jones, P. A. (2019). The effect of limb dominance on change of direction biomechanics: A systematic review of its importance for injury risk. Phys. Ther. Sport 37, 179–189. doi:10.1016/j.ptsp.2019.04.005
Dos’santos, T., Thomas, C., and Jones, P. A. (2021). Assessing interlimb asymmetries: Are we heading in the right direction? Strength & Cond. J. 43, 91–100. doi:10.1519/ssc.0000000000000590
Eirale, C., Tol, J. L., Farooq, A., Smiley, F., and Chalabi, H. (2013). Low injury rate strongly correlates with team success in Qatari professional football. Br. J. Sports Med. 47, 807–808. doi:10.1136/bjsports-2012-091040
Ellenberger, L., Jermann, J., Fröhlich, S., Frey, W. O., Snedeker, J. G., and Spörri, J. (2020a). Biomechanical quantification of deadbug bridging performance in competitive alpine skiers: Reliability, reference values, and associations with skiing performance and back overuse complaints. Phys. Ther. Sport 45, 56–62. doi:10.1016/j.ptsp.2020.05.013
Ellenberger, L., Oberle, F., Lorenzetti, S., Frey, W. O., Snedeker, J. G., and Spörri, J. (2020b). Dynamic knee valgus in competitive alpine skiers: Observation from youth to elite and influence of biological maturation. Scand. J. Med. Sci. Sports 30, 1212–1220. doi:10.1111/sms.13657
Exell, T. A., Irwin, G., Gittoes, M. J., and Kerwin, D. G. (2012). Implications of intra-limb variability on asymmetry analyses. J. Sports Sci. 30, 403–409. doi:10.1080/02640414.2011.647047
Fauno, P., and Wulff Jakobsen, B. (2006). Mechanism of anterior cruciate ligament injuries in soccer. Int. J. Sports Med. 27, 75–79. doi:10.1055/s-2005-837485
Florenes, T. W., Bere, T., Nordsletten, L., Heir, S., and Bahr, R. (2009). Injuries among male and female World Cup alpine skiers. Br. J. Sports Med. 43, 973–978. doi:10.1136/bjsm.2009.068759
Florenes, T. W., Nordsletten, L., Heir, S., and Bahr, R. (2012). Injuries among World Cup ski and snowboard athletes. Scand. J. Med. Sci. Sports 22, 58–66. doi:10.1111/j.1600-0838.2010.01147.x
Gil, S. M., Gil, J., Ruiz, F., Irazusta, A., and Irazusta, J. (2007b). Physiological and anthropometric characteristics of young soccer players according to their playing position: Relevance for the selection process. J. Strength Cond. Res. 21, 438–445. doi:10.1519/R-19995.1
Gil, S., Ruiz, F., Irazusta, A., Gil, J., and Irazusta, J. (2007a). Selection of young soccer players in terms of anthropometric and physiological factors. J. Sports Med. Phys. Fit. 47, 25–32.
Grindem, H., Logerstedt, D., Eitzen, I., Moksnes, H., Axe, M. J., Snyder-Mackler, L., et al. (2011). Single-legged hop tests as predictors of self-reported knee function in nonoperatively treated individuals with anterior cruciate ligament injury. Am. J. Sports Med. 39, 2347–2354. doi:10.1177/0363546511417085
Hagglund, M., Walden, M., Magnusson, H., Kristenson, K., Bengtsson, H., and Ekstrand, J. (2013). Injuries affect team performance negatively in professional football: An 11-year follow-up of the UEFA champions league injury study. Br. J. Sports Med. 47, 738–742. doi:10.1136/bjsports-2013-092215
Hart, N. H., Newton, R. U., Weber, J., Spiteri, T., Rantalainen, T., Dobbin, M., et al. (2020). Functional basis of asymmetrical lower-body skeletal morphology in professional Australian rules footballers. J. Strength Cond. Res. 34, 791–799. doi:10.1519/JSC.0000000000002841
Hewett, T. E., Ford, K. R., and Myer, G. D. (2006). Anterior cruciate ligament injuries in female athletes: Part 2, a meta-analysis of neuromuscular interventions aimed at injury prevention. Am. J. Sports Med. 34, 490–498. doi:10.1177/0363546505282619
Hewett, T. E., Myer, G. D., Ford, K. R., Heidt, R. S., Colosimo, A. J., Mclean, S. G., et al. (2005). Biomechanical measures of neuromuscular control and valgus loading of the knee predict anterior cruciate ligament injury risk in female athletes: A prospective study. Am. J. Sports Med. 33, 492–501. doi:10.1177/0363546504269591
Hibbs, A. E., Thompson, K. G., French, D., Wrigley, A., and Spears, I. (2008). Optimizing performance by improving core stability and core strength. Sports Med. 38, 995–1008. doi:10.2165/00007256-200838120-00004
Impellizzeri, F. M., Rampinini, E., Maffiuletti, N., and Marcora, S. M. (2007). A vertical jump force test for assessing bilateral strength asymmetry in athletes. Med. Sci. Sports Exerc 39, 2044–2050. doi:10.1249/mss.0b013e31814fb55c
Kellis, E., and Katis, A. (2007). Biomechanical characteristics and determinants of instep soccer kick. J. Sports Sci. Med. 6, 154–165.
Knapik, J. J., Bauman, C. L., Jones, B. H., Harris, J. M., and Vaughan, L. (1991). Preseason strength and flexibility imbalances associated with athletic injuries in female collegiate athletes. Am. J. Sports Med. 19, 76–81. doi:10.1177/036354659101900113
Kröll, J., Spörri, J., Gilgien, M., Schwameder, H., and Müller, E. (2016). Effect of ski geometry on aggressive ski behaviour and visual aesthetics: Equipment designed to reduce risk of severe traumatic knee injuries in alpine giant slalom ski racing. Br. J. Sports Med. 50, 20–25. doi:10.1136/bjsports-2015-095433
Krosshaug, T., Steffen, K., Kristianslund, E., Nilstad, A., Mok, K. M., Myklebust, G., et al. (2016). The vertical drop jump is a poor screening test for ACL injuries in female elite soccer and handball players: A prospective cohort study of 710 athletes. Am. J. Sports Med. 44, 874–883. doi:10.1177/0363546515625048
Lees, A., Asai, T., Andersen, T. B., Nunome, H., and Sterzing, T. (2010). The biomechanics of kicking in soccer: A review. J. Sports Sci. 28, 805–817. doi:10.1080/02640414.2010.481305
Leppanen, M., Pasanen, K., Kulmala, J. P., Kujala, U. M., Krosshaug, T., Kannus, P., et al. (2016). Knee control and jump-landing technique in young basketball and floorball players. Int. J. Sports Med. 37, 334–338. doi:10.1055/s-0035-1565104
Lijewski, M., Burdukiewicz, A., Pietraszewska, J., Andrzejewska, J., and Stachon, A. (2021). Asymmetry of musculature and hand grip strength in bodybuilders and martial artists. Int. J. Environ. Res. Public Health 17, 4695. doi:10.3390/ijerph17134695
Maloney, S. J. (2019). The relationship between asymmetry and athletic performance: A critical review. J. Strength Cond. Res. 33, 2579–2593. doi:10.1519/JSC.0000000000002608
Mckay, A. K. A., Stellingwerff, T., Smith, E. S., Martin, D. T., Mujika, I., Goosey-Tolfrey, V. L., et al. (2022). Defining training and performance caliber: A participant classification framework. Int. J. Sports Physiol. Perform. 17, 317–331. doi:10.1123/ijspp.2021-0451
Mclean, S. G., Myers, P. T., Neal, R. J., and Walters, M. R. (1998). A quantitative analysis of knee joint kinematics during the sidestep cutting maneuver. Implications for non-contact anterior cruciate ligament injury. Bull. Hosp. Jt. Dis. 57, 30–38.
Meyer, E. G., and Haut, R. C. (2008). Anterior cruciate ligament injury induced by internal tibial torsion or tibiofemoral compression. J. Biomech. 41, 3377–3383. doi:10.1016/j.jbiomech.2008.09.023
Newton, R. U., Gerber, A., Nimphius, S., Shim, J. K., Doan, B. K., Robertson, M., et al. (2006). Determination of functional strength imbalance of the lower extremities. J. Strength Cond. Res. 20, 971–977. doi:10.1519/R-5050501x.1
Parrington, L., and Ball, K. (2016). Biomechanical considerations of laterality in sport. Laterality Sports 2016, 279–308. doi:10.1016/B978-0-12-801426-4.00013-4
Paterno, M. V., Schmitt, L. C., Ford, K. R., Rauh, M. J., Myer, G. D., Huang, B., et al. (2010). Biomechanical measures during landing and postural stability predict second anterior cruciate ligament injury after anterior cruciate ligament reconstruction and return to sport. Am. J. Sports Med. 38, 1968–1978. doi:10.1177/0363546510376053
Rahnama, N., Lees, A., and Bambaecichi, E. (2005). Comparison of muscle strength and flexibility between the preferred and non-preferred leg in English soccer players. Ergonomics 48, 1568–1575. doi:10.1080/00140130500101585
Rouissi, M., Chtara, M., Bragazzi, N. L., Haddad, M., and Chamari, K. (2018). Data concerning isometric lower limb strength of dominant versus not-dominant leg in young elite soccer players. Data Brief 17, 414–418. doi:10.1016/j.dib.2018.01.022
Rouissi, M., Chtara, M., Owen, A., Chaalali, A., Chaouachi, A., Gabbett, T., et al. (2016). Effect of leg dominance on change of direction ability amongst young elite soccer players. J. Sports Sci. 34, 542–548. doi:10.1080/02640414.2015.1129432
Spörri, J., Kröll, J., Fasel, B., Aminian, K., and Müller, E. (2017). The use of body worn sensors for detecting the vibrations acting on the lower back in alpine ski racing. Front. Physiology 8, 522. doi:10.3389/fphys.2017.00522
Stolen, T., Chamari, K., Castagna, C., and Wisloff, U. (2005). Physiology of soccer: An update. Sports Med. 35, 501–536. doi:10.2165/00007256-200535060-00004
Supej, M., Ogrin, J., and Holmberg, H. C. (2018). Whole-body vibrations associated with alpine skiing: A risk factor for low back pain? Front. Physiol. 9, 204. doi:10.3389/fphys.2018.00204
Westin, M., Harringe, M. L., Engstrom, B., Alricsson, M., and Werner, S. (2018). Risk factors for anterior cruciate ligament injury in competitive adolescent alpine skiers. Orthop. J. Sports Med. 6, 2325967118766830. doi:10.1177/2325967118766830
Westin, M., Mirbach, L. I., and Harringe, M. L. (2022a). Side-to-side differences in knee laxity and side hop test may predispose an anterior cruciate ligament reinjury in competitive adolescent alpine skiers. Front. Sports Act. Living 4, 961408. doi:10.3389/fspor.2022.961408
Westin, M., Norlén, A., Harringe, M., and Werner, S. (2022b). A screening instrument for side dominance in competitive adolescent alpine skiers. Front. Sports Act. Living 4 4, 949635. doi:10.3389/fspor.2022.949635
Zazulak, B. T., Hewett, T. E., Reeves, N. P., Goldberg, B., and Cholewicki, J. (2007). Deficits in neuromuscular control of the trunk predict knee injury risk: A prospective biomechanical-epidemiologic study. Am. J. Sports Med. 35, 1123–1130. doi:10.1177/0363546507301585
Keywords: athletes, alpine skiing, soccer, performance, injury prevention, exercise test
Citation: Hanimann J, Ellenberger L, Bernhard T, Franchi MV, Roth R, Faude O and Spörri J (2023) More than just a side effect: Dynamic knee valgus and deadbug bridging performance in youth soccer players and alpine skiers have similar absolute values and asymmetry magnitudes but differ in terms of the direction of laterality. Front. Physiol. 14:1129351. doi: 10.3389/fphys.2023.1129351
Received: 21 December 2022; Accepted: 21 February 2023;
Published: 08 March 2023.
Edited by:
Elena Mainer Pardos, Universidad San Jorge, SpainReviewed by:
Antonio Cartón Llorente, Universidad San Jorge, SpainÖzgür Eken, İnönü University, Türkiye
Copyright © 2023 Hanimann, Ellenberger, Bernhard, Franchi, Roth, Faude and Spörri. This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY). The use, distribution or reproduction in other forums is permitted, provided the original author(s) and the copyright owner(s) are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms.
*Correspondence: Jonas Hanimann, am9uYXMuaGFuaW1hbm5AYmFsZ3Jpc3QuY2g=