Sage Journals: Discover world-class research

Abstract

This study examined how hand dominance influences lower-limb biomechanics during single-leg landing in bilateral lay-ups. Because the lay-up is a high-frequency basketball skill that imposes substantial impact loading and requires rapid neuromuscular control, side-dependent landing strategies may contribute to asymmetrical joint loading and elevate injury risk, particularly at the knee and ankle. However, empirical evidence clarifying how hand dominance interacts with lay-up side to shape landing biomechanics remains limited. Thirty male collegiate basketball players (15 left-hand dominant, 15 right-hand dominant) performed standardized right-hand lay-ups with left-leg landing and left-hand lay-ups with right-leg landing on force plates under 3D motion capture. Vertical ground reaction force (VGRF) and sagittal-plane knee and ankle kinematics and kinetics were analyzed using 2 × 2 mixed ANOVA and SnPM1D over the normalized stance phase. Left-hand–dominant players exhibited higher VGRF first peaks (p = 0.001), second peaks (p = 0.012) and total impulse (p < 0.001), with pronounced side-to-side asymmetry, whereas right-hand–dominant players showed more symmetrical loading between lay-up directions. At the joint level, significant Handedness and Side interactions were found for sagittal ROM, peak flexion, joint moments and power. Left-hand–dominant athletes relied on greater knee flexion, higher knee extensor moments and larger ankle and knee power on their preferred support leg. SnPM1D revealed time-dependent differences clustered in early–mid stance (impact attenuation) and late stance (push-off).These findings indicate that hand dominance systematically reorganizes proximal–distal coordination and load distribution during lay-up landings, and that monitoring asymmetry, particularly in left-hand–dominant athletes, may be important for targeted training and injury prevention.

Keywords

Asymmetry ground reaction force motion capture motor lateralization proximal-distal coordination

Get full access to this article

View all access options for this article.

References

Stojanović

Stojiljković

Scanlan

, et al. The activity demands and physiological responses encountered during basketball match-play: a systematic review. Sports Med 2018; 48: 111–135.

Taylor

Ford

Nguyen

A-D

, et al. Biomechanical comparison of single-and double-leg jump landings in the sagittal and frontal plane. Orthop J Sports Med 2016; 4: 2325967116655158.

Pappas

Hagins

Sheikhzadeh

, et al. Biomechanical differences between unilateral and bilateral landings from a jump: gender differences. Clin J of Sport Med 2007; 17: 263–268.

Yeow

Lee

Goh

. Sagittal knee joint kinematics and energetics in response to different landing heights and techniques. Knee 2010; 17: 127–131.

Yeow

Lee

Goh

. An investigation of lower extremity energy dissipation strategies during single-leg and double-leg landing based on sagittal and frontal plane biomechanics. Hum Mov Sci 2011; 30: 624–635.

Beaulieu

McLean

. Sex-dimorphic landing mechanics and their role within the noncontact ACL injury mechanism: evidence, limitations and directions. Sports Med Arthrosc Rehabil Ther Technol 2012; 4: 10.

Fong

DT-P

Hong

Chan

L-K

, et al. A systematic review on ankle injury and ankle sprain in sports. Sports Med 2007; 37: 73–94.

Dai

Herman

Liu

, et al. Prevention of ACL injury, part I: injury characteristics, risk factors, and loading mechanism. Res Sports Med 2012; 20: 180–197.

Sadeghi

Allard

Prince

, et al. Symmetry and limb dominance in able-bodied gait: a review. Gait Posture 2000; 12: 34–45.

10.

Wang

Zhang

. Ankle biomechanics of the three-step layup in a basketball player with chronic ankle instability. Sci Rep 2023; 13: 18667.

11.

Benito-de-Pedro

Delgado-Delgado

Aguilera-Rubio

, et al. Activation of the ankle musculature during the layup gesture in basketball players with chronic ankle instability, a case control study. PLOS ONE 2025; 20: e0336380.

12.

Jamkrajang

Mongkolpichayaruk

Limroongreungrat

, et al. The effect of arm dominance on knee joint biomechanics during basketball block shot single-leg landing. J Hum Kinet 2022; 83: 13.

13.

Wolpert

Diedrichsen

Flanagan

. Principles of sensorimotor learning. Nat Rev Neurosci 2011; 12: 739–751.

14.

Serrien

Ivry

Swinnen

. Dynamics of hemispheric specialization and integration in the context of motor control. Nat Rev Neurosci 2006; 7: 160–166.

15.

Sainburg

. Evidence for a dynamic-dominance hypothesis of handedness. Exp Brain Res 2002; 142: 241–258.

16.

Cortis

Tessitore

Lupo

, et al. Inter-Limb coordination, strength, jump, and sprint performances following a youth men's basketball game. J Strength Cond Res 2011; 25: 135–142.

17.

Chaudhari

Hearn

Andriacchi

. Sport-Dependent variations in arm position during single-limb landing influence knee loading:implications for anterior cruciate ligament injury. Am J Sports Med 2005; 33: 824–830.

18.

Cen

Song

, et al. Influence of medial longitudinal arch flexibility on lower limb joint coupling coordination and gait impulse. Gait Posture 2024; 114: 208–214.

19.

Wang

Song

Sun

, et al. Biomechanical trade-offs in knee brace stiffness: Dynamic stability during single-leg lateral landings in young males. IEEE T Neur Sys Reh 2026; 34: 626–637.

20.

Gao

Song

Sun

, et al. Impact of Becker muscular dystrophy on gait patterns: insights from biomechanical analysis. Gait Posture 2025; 121: 160–165.

21.

Song

Cen

Wang

, et al. A systematic review of finite element analysis in running footwear biomechanics: insights for running-related musculoskeletal injuries. J Sport Sci Med 2025; 24: 370–387.

22.

Gao

Gusztáv

Gao

. Effects of loading positions on lower limb biomechanics during lunge squat in men with different training experience. Physical Activity and Health 2025; 9: 198–213.

23.

Chang

Cen

. Can running technique modification benefit patellofemoral pain improvement in runners? A systematic review and meta-analysis. Int J Biomed Eng Tec 2024; 45: 83–101.

24.

Nin

Lam

Kong

. Effect of body mass and midsole hardness on kinetic and perceptual variables during basketball landing manoeuvres. J Sports Sci 2016; 34: 756–765.

25.

Schmida

Wille

S-J

, et al. Vertical loading rate is not associated with running injury, regardless of calculation method. Med Sci Sports Exerc 2022; 54: 1382–1388.

26.

Chinnasee

Weir

Sasimontonkul

, et al. A biomechanical comparison of single-leg landing and unplanned sidestepping. Int J Sports Med 2018; 39: 636–645.

27.

Di Paolo

Buckthorpe

Pirli Capitani

, et al. Boosting the clinical use of ground reaction forces in anterior cruciate ligament injury prevention: The ‘CUTtheACL’study. Knee Surg Sports Traumatol Arthrosc 2025; 33: 4059–4069.

28.

Giesche

Wilke

Engeroff

, et al.

Are biomechanical stability deficits during unplanned single-leg landings related to specific markers of cognitive function?

J Sci Med Sport 2020; 23: 82–88.

29.

Ohji

Aizawa

Hirohata

, et al. Correlations between vertical ground reaction force, sagittal joint angles, and the muscle co-contraction index during single-leg jump-landing. Asian J Sports Med 2019; 10: e81771.

30.

Suzuki

Ishida

Matsumoto

, et al. Relationship between vertical ground reaction force and acceleration from wearable inertial measurement units during single-leg drop landing after anterior cruciate ligament reconstruction. Appl Sci 2025; 15: 1583.

31.

Sarvestan

Fakhraei Rad

. Lower limb joint coordination and coordination variability during landing: a scoping review. Appl Sci 2025; 15: 5118.

32.

Myer

Ford

Di Stasi

, et al.

High knee abduction moments are common risk factors for patellofemoral pain (PFP) and anterior cruciate ligament (ACL) injury in girls: is PFP itself a predictor for subsequent ACL injury?

Br J Sports Med 2015; 49: 118–122.

33.

Fong

C-M

Blackburn

Norcross

, et al. Ankle-dorsiflexion range of motion and landing biomechanics. J Athl Train 2011; 46: 5–10.

34.

Acar

Umutlu

Gencer

, et al. Strength asymmetries and their impact on landing dynamics during countermovement jump and drop jump tests in professional female basketball players. BMC Sports Sci Med Rehabil 2025; 17: 82.

35.

Wang

Qin

Zhang

. Association between pre-season lower limb interlimb asymmetry and non-contact lower limb injuries in elite male volleyball players. Sci Rep 2025; 15: 14481.

36.

Legg

Donahue

Peel

, et al. Effects of shoe collar height and limb dominance on landing knee biomechanics in female collegiate volleyball players. J Sports Sci 2024; 42: 247–254.

37.

Bishop

Turner

Read

. Effects of inter-limb asymmetries on physical and sports performance: a systematic review. J Sports Sci 2018; 36: 1135–1144. 2017/08/03. DOI: 10.1080/02640414.2017.1361894.

38.

Gilbert

Van Valkenburg

, et al. Reactive signal complexity influences biomechanical variables associated with ACL loading risk. J Biomech 2025; 192: 112968.

Comparative analysis of knee and ankle joint biomechanics during single-leg landing in bilateral lay-ups: Influence of hand dominance in basketball players

Abstract

Keywords

Get full access to this article

References