| Research article - (2026)25, 656 - 664 DOI: https://doi.org/10.52082/jssm.2026.656 |
| Dominant Leg Continuous Unilateral Hopping Impairs Contralateral Leg But Not Upper Body Explosive Performance |
Mahta Sardroodian, Hiwa Rahmani, David G. Behm |
| Key words: Crossover fatigue, jump, rebound, reactive strength index, power, contact time |
| Key Points |
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| Participants |
An a priori statistical power analysis was conducted (F test for repeated measures ANOVA within factors) based on prior related research (Halperin et al., All participants completed all experimental sessions. Participants were recreationally active (participated in dynamic exercise more than 2 times per week) and free from known musculoskeletal, neurological, or cardiovascular conditions that could affect performance. Eligibility was confirmed using the Physical Activity Readiness Questionnaire (PAR-Q+) (Bredin et al., |
| Experimental design |
Participants attended the laboratory on four separate occasions (randomized order) for familiarization, control, continuous fatigue, and intermittent fatigue sessions. An initial familiarization session was incorporated to ensure learning effects were minimized. For the randomization, a random number was assigned to each condition for each participant using the random number function in Microsoft Excel and then sorted the values to determine the order of the sessions. Experimental sessions were separated by a minimum of 48 hours to allow for adequate recovery. During the continuous fatigue session, participants completed a single 1-min bout of unilateral hopping using the dominant leg. Based on the findings of Duchateau et al.,( In a prior review (Halperin et al., |
| General procedures |
At the beginning of each session, participants completed a standardized warm-up consisting of 5 min cycling on a stationary ergometer at a self-selected comfortable pace. Following the warm-up, participants completed pre-test assessments for lower- and upper-body explosive performance. Throughout all fatigue protocols and performance tests, standardized verbal encouragement was provided by the investigator to ensure consistent maximal effort across sessions. Verbal encouragement involved loudly exhorting the word “go” to the participants every 5 seconds during the fatigue protocol and every 2 seconds during the testing protocols. All testing procedures and data collection were conducted by the same investigator. |
| Performance assessments | |
Lower-body explosive performance was assessed using a unilateral leg hop test performed with the non-dominant leg. Upper-body explosive performance was assessed using a push-up rebound test. All hop and rebound push-up assessments were conducted using a portable contact mat system (Chronojump Boscosystem; Chronojump, Barcelona, Spain, 59.0 × 84.1 cm). The system records contact and flight times via a pressure-sensitive platform connected to dedicated acquisition software. From these measurements, hop or rebound push-up height (cm), power (Watts), and reactive strength index (RSI; m·s-1) were calculated using established flight-time methods. The Chronojump Boscosystem calculates average mechanical power from flight-time data recorded by the contact mat. The Chronojump Boscosystem provides an indirect estimate of mechanical power derived from jump timing assumptions rather than a direct force-plate measurement. Chronojump's equation for power uses mean flight time and number of jumps as follows:
Based on the actual raw measurements (i.e., flight time), the Chronojump system has demonstrated high validity and reliability for assessing vertical jump performance (ICC = 0.999-1.000; CV = 4.28 ± 1.95%) in active populations (Pueo et al., 2020). However, these estimates should be interpreted cautiously as an indirect proxy derived from flight-time rather than a direct measure of mechanical power. During the push-up rebound test, participants placed their hands directly on the contact mat at shoulder width. With the rebound push-ups, participants had to make contact to the floor with their chest while maintaining a horizontal trunk position. Male participants adopted a standard push-up position (hands and feet in contact with the floor, with a straight trunk), whereas female participants performed a modified push-up with the knees in contact with the floor. Standard push-ups produce a relative (to body mass) ground reaction force of 64-66% whereas modified push-ups with the knees as a contact point exert 49-53% of body mass (Ebben et al., For the 5 rebound push-ups, participants were told to “explode” (contract as quickly and forcefully as possible) off the mat and upon landing on their hands to minimize their time on the mat (brief contact time). A similar command was provided for the 10 hops. During the fatiguing hop intervention and hop tests, participants held their hands at the height of the sternum and were allowed to touch the wall with two fingers if they felt unstable when landing. The choice of 5 push-ups and 10 hops was based on pilot work demonstrating that there was greater fatigue with the push-ups and a number of participants could not perform 10 explosive rebound push-ups. The order of lower-body (10 unilateral hops) and upper-body (5 rebound push-ups) performance tests was randomized across participants and sessions to minimize order effects. A 30-second recovery period was allocated between the upper and lower body tests. The investigators observed the participants during testing to ensure proper and standardized technique. |
| Ratings of Perceived Exertion (RPE) |
RPE was collected to quantify subjective perceptions of global effort during testing. RPE was recorded using a 10-point category-ratio scale (Borg, |
| Statistical analyses |
Statistical analyses were performed using IBM SPSS Statistics (Version 29.0; IBM Corp., Armonk, NY, USA) and Jamovi (Version 2.5; The Jamovi project). Microsoft Excel (Microsoft 365; Microsoft Corp., Redmond, WA, USA) was utilized for data visualization and the creation of figures. Data in the text and tables are presented as mean ± standard deviation (SD), while data in figures are presented as mean ± standard error of the mean (SEM). The Shapiro-Wilk and Mauchly's Tests were used to assess the normality of the distribution and assumption of sphericity, respectively (P > 0.05). Since the study used a two-way (3 × 4) repeated-measures ANOVA, there were 12 repeated measurements for the RPE variable. In repeated-measures analyses, the statistical model is evaluated based on the assumptions of the repeated-measures ANOVA rather than the distribution of each individual measurement in isolation. For the RPE data, Mauchly's test indicated that the assumption of sphericity was met for the Session, Time, and Session × Time effects. Therefore, the standard repeated-measures ANOVA (sphericity assumed) was appropriate, and no Greenhouse-Geisser correction was required. To determine differences between conditions and time points, a two-way (3 × 4) repeated-measures analysis of variance (ANOVA) was conducted with Session (Intermittent, Continuous, Control) and Time (Pre, 1- min, 5- min, and 10- min after exercise) as within-subject factors. Mean data from the lower body hops (10 repetitions) and upper body rebound push-ups (5 repetitions) were analyzed. Power and RSI were considered secondary outcomes as they were calculated/derived from the primary outcomes of hop or rebound push-up height (calculated from flight time) and contact time. Sex was not included as a factor in the statistical analyses due to the small number of female participants (n = 5), which limited statistical power and precluded meaningful sex-based comparisons. Therefore, analyses were conducted on the pooled sample. When significant main effects or interactions were observed, the Bonferroni adjusted post hoc test was employed to identify specific pairwise differences. Effect sizes were assessed using partial eta squared (ηp2). Statistical significance was accepted at p ≤ 0.05 for all analyses. Partial eta2 values represent effect size magnitudes as follows: 0.01: small, 0.06: medium, 0.14 or higher: large. Reliability of the average hop (ICC (3, 10)) and rebound push-up heights (ICC (3,5)) (height as a representative of all derived measures such as power) was assessed using a two-way mixed-effects, consistency, single-measures intraclass correlation coefficient with fixed rater. |
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For all tests, the Shapiro-Wilk test of normality was non-significant suggesting data was approximately normally distributed while the Mauchly test of sphericity was also non-significant indicating sphericity was achieved. Reliability as assessed with ICC was considered high with r of 0.97 and 0.86 for hop and rebound push-up height respectively ( |
| Non-dominant leg hop performance |
Descriptive statistics for non-dominant leg performance are presented in |
| Upper body (rebound push-up) performance |
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The present study investigated the non-local effects of unilateral dynamic (hopping) fatigue of the dominant lower limb on contralateral, non-dominant, lower-limb hopping and upper-body rebound push-ups explosive performance under continuous and intermittent fatigue protocols. The major findings were that continuous dominant leg unilateral hopping impaired contralateral hop height, RSI, and lower-limb power, whereas non-dominant upper-body explosive performance during the rebound push-up task remained unaffected. Moreover, upper-body RPE (verbally recorded after the hop and rebound push-up tests at 1-, 5- and 10- minutes post-intervention) were higher following intermittent hopping than continuous. Thus, 60 seconds of continuous unilateral, dominant leg, hopping demonstrated greater impairments on contralateral lower-limb explosive performance than on upper-body explosive capacity. Contralateral impairments observed following continuous exercise performed to induce fatigue align with the concept of centrally mediated non-local fatigue (Zijdewind et al., The task-specific nature of the observed effects is noteworthy. Explosive jump performance requires more integrated motor control with rapid force development, neuromuscular timing, and coordinated multi-joint activation, possibly making it sensitive to subtle reductions in central drive (Behm et al., The time course of recovery provides further mechanistic hypotheses. Contralateral impairments were evident 1 min post-exercise but resolved within minutes, suggesting the possibility of a predominantly central origin rather than structural or metabolic changes in non-exercised limbs. As afferent feedback decreases and cortical excitability normalize (Aboodarda et al., From an applied perspective, these findings indicate that continuous unilateral plyometric exercise may transiently impair contralateral lower-limb explosive performance, whereas brief recovery intervals can mitigate such effects. Practitioners should consider exercise sequencing when unilateral fatigue-inducing tasks precede contralateral explosive movements. The rapid recovery observed suggests that short post-exercise rest may be sufficient to restore performance. |
| Limitations |
Several limitations should be acknowledged. The sample size was modest, and participants had recreational training backgrounds, limiting generalizability. It is possible that a trained or sedentary group might respond differently as they could have greater or lesser resistance to fatigue and lower or greater metabolic and neural disruptions associated with the exercise protocol respectively. We did not directly measure the extent of the intervention fatigue. However, fatigue was evident from the remarks made by participants after the intervention and visual inspection of their performance indicating poorer hop performance (height, speed, and contact time). Although global RPE was recorded after the testing protocol, it was significantly higher at 1-minute post-test for both the hop and rebound push-up conditions. This significantly higher RPE score at 1-minute may have been influenced by the prior fatiguing intervention as well as the test. We are confident that all participants experienced fatigue from the intervention. Direct neurophysiological measurements were not obtained, precluding definitive conclusions about underlying mechanisms. Unfortunately, we could not recruit a sufficient number of female participants to achieve the statistical power needed to investigate possible sex differences. As the rebound push-up test was modified for the women, the integration of this data for analysis may have introduced some generalizability issues. However, in practical terms, having women perform push-ups with their knees rather than feet as a point of contact is ubiquitous in training and testing as the lower upper body torque allows women with generally absolute and relative lower upper body strength to perform this exercise. |
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In conclusion, unilateral dynamic fatigue (hopping) of the dominant lower limb induced condition-dependent and transient impairments in contralateral lower-limb explosive performance, whereas non-dominant upper-body explosive performance remained unaffected. Continuous loading elicited measurable contralateral decrements, while the incorporation of brief recovery intervals mitigated these effects, highlighting the importance of exercise structure in the manifestation of non-local fatigue. Together, these findings indicate that the expression of non-local fatigue is task-specific, may be centrally mediated, and highly sensitive to the temporal organization of the fatiguing stimulus. The rapid recovery observed further supports the possibility of a predominantly central mechanism and suggests that short recovery periods may be sufficient to restore explosive performance capacity. |
| ACKNOWLEDGEMENTS |
We thank the participants for their time. The authors report no actual or potential conflicts of interest. While the datasets generated and analyzed in this study are not publicly available, they can be obtained from the corresponding author upon request. All experimental procedures were conducted in compliance with the relevant legal and ethical standards of the country where the study was carried out. The authors declare that no Generative AI or AI-assisted technologies were used in the writing of this manuscript. This research was partially funded through Dr. Behm’s Natural Science and Engineering Research Council of Canada (NSERC) Discovery Grant (RGPIN-223-05861). |
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