Restricted accessResearch articleFirst published online 2026
Effects of forward,backward,and combined resisted sprint training on sprint performance,sprint kinematics,and isokinetic knee muscle function in recreational soccer players
This study aimed to compare the effects of forward, backward, and combined (i.e., forward and backward exercises) resisted sprint training on sprint performance, sprint kinematics, and isokinetic knee muscle function in recreational soccer players. Thirty-six recreational male soccer players were randomly assigned to forward, backward, or combined resisted sprint training and completed a 6-week intervention (two sessions per week) using sled resistance corresponding to 20–55% of body mass. Sprint performance (5–20 m), spatiotemporal and kinematic sprint variables, and isokinetic knee muscle strength and power were assessed before and after training. Sprint performance over 5 m, 10 m, and 20 m improved significantly following the intervention (p < 0.001), with no significant time × group interactions. Trunk angle exhibited a significant time × group interaction (p < 0.05), with reductions observed in the forward and combined training groups only. No significant changes were observed in stride length or stride frequency. Knee muscle eccentric strength and concentric power increased significantly across all groups (p < 0.001), with comparable adaptation magnitudes. Forward, backward, and combined resisted sprint training effectively improved sprint performance and knee muscle function in recreational soccer players. Direction-specific trunk angle adaptations indicate distinct kinematic responses to different training modalities, supporting the potential use of combined resisted sprint training as a practical training option. Practically, resisted sprint training using light-to-moderate external loads appears effective for improving short-distance sprint performance and knee muscle function in amateur soccer players.
NicholsonBDinsdaleAJonesB, et al.The training of short distance sprint performance in football code athletes: a systematic review and meta-analysis. Sports Med2021; 51: 1179–1207.
2.
ZabaloySPereiraLADrozdM, et al.Implementing resisted and unresisted sprint training across multiple sports: practical guidelines and considerations. Hum Mov2025; 26: 26–43.
3.
Di SalvoVBaronRGonzález-HaroC, et al.Sprinting analysis of elite soccer players during European champions league and UEFA cup matches. J Sports Sci2010; 28: 1489–1494.
4.
FaudeOKochTMeyerT. Straight sprinting is the most frequent action in goal situations in professional football. J Sports Sci2012; 30: 625–631.
5.
AndrzejewskiMChmuraJPlutaB, et al.Analysis of sprinting activities of professional soccer players. J Strength Cond Res2013; 27: 2134–2140.
6.
RumpfMCLockieRGCroninJB, et al.Effect of different sprint training methods on sprint performance over various distances: a brief review. J Strength Cond Res2016; 30: 1767–1785.
7.
BolgerRLyonsMHarrisonAJ, et al.Sprinting performance and resistance-based training interventions: a systematic review. J Strength Cond Res2015; 29: 1146–1156.
8.
PetrakosGMorinJEganB. Resisted sled sprint training to improve sprint performance: a systematic review. Sports Med2016; 46: 381–400.
9.
UthoffAOliverJCroninJ, et al.Resisted sprint training in youth: the effectiveness of backward vs. Forward sled towing on speed, jumping, and leg compliance measures in high-school athletes. J Strength Cond Res2021; 35: 2205–2212.
10.
BehrensMJSimonsonSR. A comparison of the various methods used to enhance sprint speed. Strength Condit J2011; 33: 64–71.
11.
AlcarazPEPalaoJMElviraJL, et al.Effects of three types of resisted sprint training devices on the kinematics of sprinting at maximum velocity. J Strength Cond Res2008; 22: 890–897.
12.
AldrichEKSullivanKWingoJE, et al.The effect of resisted sprint training on acceleration: a systematic review and meta-analysis. Int J Exerc Sci2024; 17: 986–1002.
13.
SinclairJEdmundsonCJMetcalfeJ, et al.The effects of sprint vs. Resisted sled-based training; an 8-week in-season randomized control intervention in elite rugby league players. Int J Environ Res Public Health2021; 18: 9241.
14.
ZabaloySFreitasTTPareja-BlancoF, et al.Narrative review on the use of sled training to improve sprint performance in team sport athletes. Strength Cond J2023; 45: 13–28.
15.
JawedFAnsariSAzizR, et al.An evaluation of physical performance in collegiate athletes: a randomized controlled trial comparing backward and forward running. Clin Epidemiol Glob Health2024; 29: 101740.
16.
UthoffAOliverJCroninJ, et al.A new direction to athletic performance: understanding the acute and longitudinal responses to backward running. Sports Med2018; 48: 1083–1096.
17.
UthoffAOliverJCroninJ, et al.Backward running: the why and how to program for better athleticism. Strength Condit J2019; 41: 48–56.
18.
DeVitaPStriblingJ. Lower extremity joint kinetics and energetics during backward running. Med Sci Sports Exerc1991; 23: 602–610.
19.
UthoffAZoisJVan Den TillaarR, et al.Acceleration mechanics during forward and backward running: a comparison of step kinematics and kinetics over the first 20 m. J Sports Sci2021; 39: 1816–1821.
20.
UthoffAOliverJCroninJ, et al.Sprint-specific training in youth: backward running vs. Forward running training on speed and power measures in adolescent male athletes. J Strength Cond Res2020; 34: 1113–1122.
21.
González-CanoHMartín-OlmedoJJBaz-ValleE, et al.Do muscle mass and body fat differ between elite and amateur natural physique athletes on competition day? A preliminary, cross-sectional, anthropometric study. J Strength Cond Res2024; 38: 951–956.
22.
Langan-EvansCHearrisMAMcQuilliamS, et al.Hormonal contraceptive use, menstrual cycle characteristics and training/nutrition related profiles of elite, sub-elite and amateur athletes and exercisers: one size is unlikely to fit all. Int J Sports Sci Coach2024; 19: 113–128.
23.
McKayAKStellingwerffTSmithES, et al.Defining training and performance caliber: a participant classification framework. Int J Sports Physiol Perform2021; 17: 317–331.
24.
Romero-FrancoNJiménez-ReyesPCastaño-ZambudioA, et al.Sprint performance and mechanical outputs computed with an iPhone app: comparison with existing reference methods. Eur J Sport Sci2017; 17: 386–392.
25.
MildenbergerCAragonaAGuissaniC, et al.Sprint biomechanics assessment with low-cost systems: a reliability study. Sport Sci Health2024; 20: 1325–1332.
26.
García-PinillosFBujalance-MorenoPLago-FuentesC, et al.Effects of the menstrual cycle on jumping, sprinting and force-velocity profiling in resistance-trained women: a preliminary study. Int J Environ Res Public Health2021; 18: 4830.
27.
Moiroux-SahraouiAMazeasJJhingoorJ, et al.Relationship between force-velocity characteristics and sprint performance in elite sprinters: a pilot study. Cureus2024; 16: e65944.
28.
LahtiJHuuhkaTRomeroV, et al.Changes in sprint performance and sagittal plane kinematics after heavy resisted sprint training in professional soccer players. PeerJ2020; 8: e10507.
29.
MaulderPSBradshawEJKeoghJW. Kinematic alterations due to different loading schemes in early acceleration sprint performance from starting blocks. J Strength Cond Res2008; 22: 1992–2002.
30.
CroninJHansenKKawamoriN, et al.Effects of weighted vests and sled towing on sprint kinematics. Sports Biomech2008; 7: 160–172.
31.
TuominenJLeppänenMJarskeH, et al.Test− retest reliability of isokinetic ankle, knee and hip strength in physically active adults using biodex system 4 pro. Methods Protoc2023; 6: 26.
32.
GrossMTHuffmanGMPhillipsCN, et al.Intramachine and intermachine reliability of the Biodex and Cybex® II for knee flexion and extension peak torque and angular work. J Orthop Sports Phys Ther1991; 13: 329–335.
33.
HoriMSugaTTeradaM, et al.Relationship of the knee extensor strength but not the quadriceps femoris muscularity with sprint performance in sprinters: a reexamination and extension. BMC Sports Sci Med Rehabilitation2021; 13: 67.
34.
MorinJCapelo-RamirezFRodriguez-PérezMA, et al.Individual adaptation kinetics following heavy resisted sprint training. J Strength Cond Res2022; 36: 1158–1161.
35.
HunterJPMarshallRNMcNairPJ. Interaction of step length and step rate during sprint running. Med Sci Sports Exerc2004; 36: 261–271.
36.
BezodisI. Investigations of the step length-step frequency relationship in sprinting: applied implications for performance. In: Proceedings of the 30th International Conference on Biomechanics in Sports, 2012, pp. 43–49.
37.
MyrvangSvan den TillaarR. The longitudinal effects of resisted and assisted sprint training on sprint kinematics, acceleration, and maximum velocity: a systematic review and meta-analysis. Sports Med Open2024; 10: 110.
38.
ClarkKPStearneDJWaltsCT, et al.The longitudinal effects of resisted sprint training using weighted sleds vs. weighted vests. J Strength Cond Res2010; 24: 3287–3295.
39.
ZabaloySHealyRPereiraLA, et al.A randomized controlled trial of unresisted vs. Heavy resisted sprint training programs: effects on strength, jump, unresisted and resisted sprint performance in youth rugby union players. J Hum Kinet2025; 95: 199.
40.
ZabaloySPereiraLAGálvez-GonzálezJ, et al.The effectiveness of unresisted versus heavy resisted sprints on sprint speed, strength deficit, and force–time measures in youth rugby players. Int J Sports Physiol Perform2026; 1: 1–10.
41.
RepulloCCastaño-ZambudioADel Campo-VecinoJ, et al.Resisted sprint training with combined loads improve the maximum velocity in professional female soccer. Sports Biomech2025; 24: 2310–2327.
