Single-Leg Squat Compensations Are Associated With Softball Pitching Pathomechanics in Adolescent Softball Pitchers.

BACKGROUND: A lack of lumbopelvic-hip complex (LPHC) stability is often associated with altered pitching mechanics, thus increasing pain and injury susceptibility. The single-leg squat (SLS) is a simple diagnostic tool used to examine LPHC stability.
PURPOSE: To examine the relationship between trunk compensatory kinematics during the SLS and kinematics at foot contact during the windmill pitch. STUDY
DESIGN: Descriptive laboratory study.
METHODS: Participants included 55 youth and high school softball pitchers (mean age, 12.6 ± 2.2 years; height, 160.0 ± 11.0 cm; weight, 60.8 ± 15.5 kg). Kinematic data were collected at 100 Hz using an electromagnetic tracking device. Participants were asked to complete an SLS on each leg, then throw 3 fastballs at maximal effort. Values of trunk flexion, trunk lateral flexion, and trunk rotation at peak depth of the SLS were used as the dependent variables in 3 separate backward-elimination regression analyses. Independent variables examined at foot contact of the pitch were as follows: trunk flexion, trunk lateral flexion, trunk rotation, center of mass, stride length, and stride knee valgus.
RESULTS: The SLS trunk rotation regression (F(1,56) = 4.980, P = .030) revealed that trunk flexion predicted SLS trunk rotation (SE = 0.068, t = 2.232, P = .030) and explained approximately 7% of the variance in SLS trunk rotation (R 2 = 0.083, adjusted R 2 = 0.066). The SLS trunk flexion regression (F(1,56) = 5.755, P = 0.020) revealed that stride knee valgus significantly predicted SLS trunk flexion (SE = 0.256, t = 2.399, P = .020) and explained approximately 8% of variance in SLS trunk flexion (R 2 = 0.095, adjusted R 2 = 0.078).
CONCLUSION: Additional trunk rotation and trunk flexion at peak depth of the SLS showed increased knee valgus and trunk flexion at foot contact of the pitch, both of which indicate poor LPHC stability during the softball pitch and may increase the potential for injury. CLINICAL RELEVANCE: Players and coaches should implement SLS analyses to determine their players' risk for injury and compensation due to poor core stability.

Despite the perception that pitching is an upper-extremity activity, proper utilization of the lower extremity and trunk is needed for optimal performance and decreased injury susceptibility. Softball pitching is a full-body dynamic and sequential movement that relies heavily on lower-extremity contribution to achieve maximal pitch velocity, control, accuracy, and proper mechanics. This total-body dynamic movement is the result of the integrated, multisegmented system of the body acting as a kinetic chain. Kinetic chain efficiency is accomplished when the proximal or lower extremity can generate and produce maximal energy and force to be transferred through the trunk and on to the distal upper extremity and into the ball. Any alteration in force generation or transfer results in a disruption in the kinetic chain, placing undue stress on injury-susceptible joints. While most literature regarding softball pitching mechanics focuses solely on the upper extremity, research has shown the importance of proximal to distal sequencing via the kinetic chain.

Typically, dynamic upper extremity movements utilize the proximal lower extremity to generate 50% to 55% of the total energy generated at the distal end of the chain. However, for the efficient transfer of energy from the lower to upper extremity, there must be lumbopelvic-hip complex (LPHC) stability. Stability of the LPHC during dynamic upper-extremity movements is commonly associated with gluteal muscle activation resulting in pelvic stability. It has been theorized that the LPHC provides the proximal stability for distal mobility, highlighting the role of the LPHC in providing a stable platform against which distal muscles can pull and accelerate. Therefore, we define LPHC control as the ability to stabilize the LPHC in an effort to mobilize segments distal to the trunk. Specific to dynamic upper extremity movement, we see the effect of LPHC control in trunk kinematics and pitch volume. Additionally, it is known that the musculature of the lower extremity is active during the softball pitch, and it is the activation of the gluteal musculature in both the drive and stride leg that controls the trunk in softball pitching.

Examination of LPHC control and stability is commonly performed through the assessment of a single-leg squat (SLS). The SLS is a reliable assessment of LPHC strength, sport performance, and lower-extremity pain. Those with reduced LPHC stability often display compensatory mechanics of knee valgus, pelvic tilt, trunk lean, and trunk rotation. The functional stability of the LPHC is fundamentally supplied through the activation of the gluteal muscle group. Specifically, the gluteal muscle group allows for stabilization of the trunk over single-leg support. Thus, SLS assessment of LPHC stability emphasizes weakness in the gluteal muscle group resulting in kinematic compensations of knee valgus, trunk flexion, and trunk rotation.

An examination of the literature regarding LPHC stability and upper-extremity dynamic movement, specifically in baseball, revealed that a lack of LPHC stability during the SLS is often associated with altered pitching mechanics, thus increasing pain and injury susceptibility. Based on the known compensatory patterns displayed in SLS assessment, we hypothesized that individuals who display greater knee valgus, trunk flexion, and/or trunk rotation during the SLS may also display trunk compensations during a dynamic upper-extremity movement, such as the windmill softball pitch. Trunk kinematics during the windmill pitch have previously been shown to differentiate those softball pitchers who currently experience upper-extremity pain from those who do not. More specifically, those with upper-extremity pain display differences in trunk flexion, trunk rotation, stride length, and center of mass positioning during the windmill pitch. Therefore, it seems plausible that those who display poor LPHC stability via SLS compensation may also exhibit trunk and lower-extremity pathomechanics during the windmill pitch previously associated with upper-extremity pain.

With the known injury susceptibility in windmill softball pitching, a thorough understanding of the association of LPHC stability and pitching mechanics is needed. The purpose of this study was to examine the relationship between trunk compensatory kinematics during the SLS and kinematics during foot contact of the windmill pitch. We hypothesized that there would be a relationship between SLS compensations and pitch kinematics previously associated with injury. In using a simple clinical assessment, such as the SLS, athletes, coaches, parents, and clinicians can identify potential risk factors that may predispose the athlete to previously recognized potentially injurious movement patterns during the softball pitch.

Methods

A total of 55 youth and high school softball pitchers (mean age, 12.6 ± 2.2 years; height, 160.0 ± 11.0 cm; weight, 60.8 ± 15.5 kg) were recruited to participate. Inclusion criteria included no lower- or upper-extremity injuries in the past 6 months and no history of surgery to the upper or lower extremity. The university’s institutional review board approved all testing protocols. Before data collection, all testing procedures were explained to each participant and informed assent and parental consent were obtained.

Participants reported to the laboratory for testing before engaging in any throwing or vigorous physical activity that day. After the study explanation, 14 electromagnetic sensors (Flock of Birds; Ascension Technologies Inc) were affixed to the skin: (1) posterior trunk at the first thoracic vertebrae (T1) spinous process; (2) posterior pelvis at the first sacral vertebrae (S1); (3-4) flat broad portion of the acromion (bilaterally); (5-6) bilateral upper arm at the deltoid tuberosity; (7-8) posterior distal forearm (bilaterally), approximately halfway between the radial and ulnar styloid processes; (9) dorsum of throwing-side hand, approximately halfway along the third metacarpal; (10-11) lateral thigh (bilaterally), approximately halfway between the greater trochanter and lateral condyle of the knee; (12-13) lateral shank (bilaterally), approximately halfway between the lateral condyle of the knee and lateral malleolus; and (14) dorsum of nonthrowing side foot, approximately halfway along the second metatarsal. A 15th sensor was attached to a movable plexiglass stylus for the digitization of bony landmarks. Sensor attachment sites are displayed in Figure 1.

Figure 1.

Image showing sensor attachment sites by body segment.

Kinematic data were collected at 100 Hz using an electromagnetic tracking device (trakSTAR; Ascension Technologies Inc) synchronized with The MotionMonitor software (Innovative Sports Training). The digitized medial and lateral aspect of each joint, and the calculated midpoint between those 2 points, were used to develop a linked segment model. Shoulder and hip joint centers were estimated using previously established rotation methods. Raw data regarding sensor position and orientation were independently filtered along each global axis using a fourth-order Butterworth filter with a cutoff frequency of 20 Hz. The world axis was represented with the positive Y-axis in the vertical direction, anterior to the Y-axis and in the direction of movement was the positive X-axis, and orthogonal and to the right of X and Y was the positive Z-axis. Position and orientation of body segments were consistent with recommendations from the International Society of Biomechanics.

After sensor attachment and system calibration, participants performed an SLS repetition on their stride (glove-arm side) leg. Participants were instructed to cross their arms over their chest, flex the nontesting knee to 90°, and to squat as low as they could while maintaining single-leg balance. After reaching peak depth, participants ascended to the starting position without letting their nontesting foot touch the ground and without letting their nontesting leg touch the testing leg. A failed trial consisted of the nontesting leg touching the ground or resting on the testing leg. Cadence for the SLS was self-selected by the participant. Participants were allowed to practice the task until they were comfortable performing a correct SLS, however they were not instructed on how to perform the SLS. This was to ensure that the participant’s preferred movement was not altered, and that measurement of the SLS was reflective of the participant’s current state of stability and skill.

After SLS performance, participants were allotted an unlimited amount of time to prepare for full-effort pitching. Individual pregame routines were allowed to ensure that each participant could most closely mimic in-game effort levels. Once participants indicated they were ready, they performed 3 full-effort fastball pitches to a catcher at regulation distance (43 ft; 13.1 m).

The pitching motion was examined at foot contact when the pitcher made initial stride foot contact with the ground (force plate). The drive leg was defined as the leg ipsilateral to the pitching arm, and the stride leg was defined as the leg contralateral to the pitching arm. Center of mass (COM) position was calculated as a percentage of the pitch, with 0% representing COM directly over the drive leg and 100% representing COM directly over the stride leg. Stride length was calculated as a percentage of the participant’s body height.

The 3 fastball pitch trials were averaged, processed using a customized MATLAB script (R2010a; MathWorks), and analyzed using SPSS Statistics 24 software (IBM). All data were considered normal according to the Shapiro-Wilk test of normality. Values of trunk flexion, trunk lateral flexion, and trunk rotation at peak depth of the SLS were used as the dependent variables in 3 separate backward linear regression analyses, 1 for each dependent variable. Independent variables included the following kinematics at foot contact during the windmill pitch: trunk flexion; trunk lateral flexion; trunk rotation; COM; stride length; and stride knee valgus. Each regression began by fitting the full model and then eliminated variables with a greater than 10% probability of an association by chance alone (P > .10) to arrive at a final restricted model. The alpha level was set a priori to α = .05.

Results

Mean kinematics during the pitch and SLS are presented in Table 1. The backward regression involving SLS trunk rotation was statistically significant, F(1, 56) = 4.980, P = .030, and revealed trunk flexion predicted SLS trunk rotation (SE = 0.068; t = 2.232; P = .030). This regression equation explained approximately 7% of the variance in SLS trunk rotation (R 2 = 0.083; adjusted R 2 = 0.066). The backward regression involving SLS trunk flexion was also statistically significant, F(1,56) = 5.755, P = .020, and revealed stride knee valgus significantly predicted SLS trunk flexion (SE = 0.256; t = 2.399; P = .020). This regression equation explained approximately 8% of variance in SLS trunk flexion (R 2 = 0.095; adjusted R 2 = 0.078). The regression analysis involving SLS trunk lateral flexion was not statistically significant. A summary of the regression models is displayed in Table 2.

Table 1

Kinematic Data During the Pitch and SLS

Variable
SLS
Peak trunk flexion, deg b	21.10 ± 12.45
Peak trunk rotation, deg c	–1.85 ± 6.26
Peak trunk lateral flexion, deg d	–3.35 ± 8.03
Pitching motion at foot contact
Trunk flexion, deg b	4.45 ± 11.92
Trunk rotation, deg c	–59.51 ± 14.26
Trunk lateral flexion, deg d	–7.86 ± 10.37
Center of mass, % e	45.70 ± 5.10
Stride length, m	0.92 ± 0.17
Stride knee flexion, deg	–25.73 ± 10.28
Stride knee valgus, deg	1.43 ± 6.24

Data are reported as mean ± SD unless otherwise indicated. SLS, single-leg squat.

Positive value = forward flexion.

Negative value = toward pitching arm.

Negative value = toward glove arm.

0% represents center of mass directly over the drive leg and 100% represents center of mass directly over the stride leg.

Table 2

Summary Table of Regression Analyses

	SLS Trunk Flexion		SLS Trunk Lateral Flexion		SLS Trunk Rotation
	Full Model	Restricted Model	Full Model	Restricted Model	Full Model	Restricted Model
R 2	0.167	0.095 b	0.095	NA	0.146	0.083 b
SE estimate	12.15	11.96	8.17		6.18	6.05
	Beta Values
Trunk flexion	0.152	—	0.227	—	0.307 b	0.288 b
Trunk rotation	–0.082	—	–0.107	—	–0.207	—
Trunk lateral flexion	0.246	—	0.030	—	–0.032	—
Stride length	0.126	—	0.037	—	0.030	—
COM, %	–0.088	—	0.191	—	0.086	—
Stance knee flexion	–0.028	—	0.125	—	–0.095	—
Stance knee valgus	0.326 b	0.308 b	–0.107	—	0.148	—

Dashes indicate variable data are not included in the final restricted model. COM, center of mass; NA, not available; SLS, single-leg squat.

Statistically significant (P < .05).

Discussion

The key findings of this study showed that (1) more trunk flexion in the SLS was associated with more knee valgus at foot contact of the softball pitch and (2) more trunk rotation during the SLS was associated with more trunk flexion at foot contact of the softball pitch (Figures 2 and 3). Both increased trunk rotation and increased trunk flexion during the SLS are typically considered flaws or compensations for those who present with less LPHC strength and stability. Often, youth athletes with LPHC weakness resort to performing the SLS with greater trunk flexion versus knee flexion. Similarly, these athletes with underdeveloped LPHC stability will often rotate toward the free leg. Therefore, both trunk flexion and trunk rotation at peak depth of the SLS are regularly indicative of poor LPHC stability.

Figure 2.

Sagittal and transverse view of the SLS at peak depth. (A) Trunk flexion (orange lines) and (B) trunk rotation (orange lines) during the SLS. SLS, single-leg squat.

Figure 3.

(A) Frontal view of the front leg. Orange lines depict knee valgus. (B) Sagittal plane of the trunk. Orange lines depict trunk flexion.

The current study has linked these aforementioned SLS compensations to specific movements during the softball pitch—specifically, increased knee valgus and trunk flexion at foot contact. Increased trunk flexion at foot contact of the windmill softball pitch has been revealed as a trait in younger, less advanced pitchers, compared with older and more elite pitching populations. Oliver et al examined youth pitchers and presented values of trunk flexion much greater than a sample of collegiate pitchers presented by Friesen et al. Contrasting values of trunk flexion display the tendency for younger athletes to rely on more distal kinetic chain segments, excluding the lower extremity, to produce pitch velocity. Specifically, it has been reported that the older, more advanced pitchers demonstrate more efficient segmental sequencing and total utilization of the kinetic chain. Thus, the current findings of those with compensations in both the SLS and during pitching could be a product of poor LPHC control. As a result, the SLS can be theorized as a tool to identify weakness, not only associated with total body strength and stability, but also as a means of identifying pitchers who may be ineffective or inefficient at controlling their body throughout the windmill pitch. Although increased trunk flexion has not been associated with an increased risk of injury, poor position of the COM has been linked to upper-extremity pain. With trunk flexion affecting COM distribution, it can be hypothesized that there may be a link between increased pitch trunk flexion and increased injury risk among softball pitchers. Ideally, pitchers need to create a stable and balanced base around which the distal arm segments can have a secure point from which to rotate.

Similar to increased trunk flexion, increased knee valgus during foot contact of the windmill softball pitch is also thought to be problematic. While the stride foot already makes high-velocity impact with the ground, increased knee valgus can load tissues and structures, again increasing the susceptibility of injury and incidence of pain. Furthermore, lower-extremity injuries are relevant in softball pitching, likely due to the large impact the stride foot withstands at foot contact. Reports have shown the stride foot develops ground reaction forces near 140% body weight; therefore, increased knee valgus during stride foot contact is worrisome. While more trunk rotation during the SLS is considered to be a compensatory technique for the less-skilled athletes completing the SLS, increased knee valgus at foot contact of the softball pitch similarly demonstrates inefficient LPHC stability. With these findings, it can be suggested that the SLS can be used as a simple analytic technique to view pitchers’ abilities, especially in terms of LPHC stability throughout a dynamic movement.

The limitations of this study include the laboratory environment. Although asked to pitch at full-effort as in a game setting, the less-intense laboratory environment can hinder true performance level. Another limitation is that pitchers’ prior experience with SLS was not accounted for; however, it can be assumed that many of the pitchers of the same age group and region of the state would have similar training practices. Similarly, SLS peak depth was not instructed or standardized, meaning pitchers may have achieved differing levels of depth that could affect other SLS kinematics and results. It is also important to note that these regression equations did not explain a profound amount of variance within the SLS variables. It can be argued that athletes can isolate training to solely improve SLS performance and not pitch mechanics, but the idea is that as players improve their trunk and core stability, they might also be able to improve their pitch mechanics, namely core stability, upon stride foot contact. Last, the sensor fixation to the skin is potentially susceptible to movement artifact, although every effort was made to properly secure the sensors with tape and adhesive spray.

Conclusion

The present study showed that compensations during the SLS, which were previously related with upper-extremity pain, were associated with pathomechanics during the softball pitch. Therefore, those pitchers who present increased trunk flexion and rotation during the SLS may pose an increased risk of injury throughout the windmill softball pitch and should, therefore, work to develop trunk strength and stability in an effort to minimize risk of injury and improve both SLS and pitch mechanics. The SLS is a simple tool that coaches and parents can use to determine an athlete’s LPHC stability and subsequent risk of softball pitching injury. If a player presents these easily identifiable kinematics during the SLS, more care and core stability training may be given in the attempt to lessen the risk of injury and also improve softball pitching performance.