| Research article - (2026)25, 617 - 626 DOI: https://doi.org/10.52082/jssm.2026.617 |
| The Effectiveness of Passive Half-Time Interventions on Simulated Second-Half Performance in Elite Youth Soccer Players |
Brendon Skinner1, , Emily E. Munn2, Tim Roberts2, Rachelle A. Reed2, Robin T. Thorpe3,4 |
| Key words: Soccer performance, half-time recovery, compression therapy, percussive therapy, EMS therapy, athlete recovery, adolescent, youth academy, simulated match |
| Key Points |
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| Participants |
Forty-three (n = 43) male participants were recruited via sampling from Northampton Town Football Club Academy teams, with club approval obtained prior to the start of the study ( Participants were excluded where any existing or recent (within the last 2-months) lower limb injury had been sustained, or any pre-existing contraindications to any of the interventions (as detailed by the manufacturer) were reported. |
| Study design |
A single-blind, independent-subject design, randomized controlled trial was conducted. Participants were blinded to performance outcomes until testing concluded. Twenty-four hours prior to the test conditions, all participants completed a familiarization session. To establish test-retest reliability, two attempts at the Loughborough Soccer Pass Test (LSPT) were completed, reporting good reliability (ICC = 0.87) against the error scores attained, three 20-meter sprints, and self-administered interventions (Le Moal et al., Participants were then randomly assigned (via computerized random number generation) to one of four half-time intervention groups: (1) Control group of passive rest (CON), (2) Percussive Therapy (Theragun PRO 4th Generation, Therabody Inc, California, US; TG), (3) Electrical Muscle Stimulation (PowerDot, Therabody Inc, California, USA; PD), (4) Pneumatic Compression (RecoveryAir PRO, model 737R, Therabody Inc, California, USA; COMP). Participants were blinded to all other conditions and only familiarised to the intervention of their allocation. |
| Simulated soccer match |
The simulation included a warm-up, the Loughborough Soccer Pass Test (LSPT) ( A meaningful attenuation of decline was defined statistically as a small-to-medium standardized effect size (Cohen's d = 0.20-0.50) and practically as any reduction in performance decay that maintains a player’s passing accuracy and sprint capability closer to their baseline (first-half) standard, which could influence critical in-game transitional moments during the opening stages of the second half. Three performance metrics were recorded: 1) LSPT-time (duration to complete 16 passes, excluding penalties), 2) LSPT penalty-time (cumulative time from errors), and 3) LSPT total-performance (sum of LSPT-time and penalty-time) (Impellizzeri et al., |
| Total Quality of Recovery (TQR) |
TQR, a non-invasive measure of perceived recovery, was recorded before each half of simulated play. Scores range from 6 to 20, with 6 representing poor (very, very low) recovery and 20 indicating maximal (very, very good) recovery, like Borg’s RPE scale for which participants were asked “how would you rate your overall recovery?”. TQR was collected after first-half testing (pre-intervention) and after second-half testing (post-intervention), based on prior associations with muscle damage biomarkers (Osiecki et al., |
| Interventions |
Control Group (CON): Participants rested passively for 15 minutes without doing any stretching or reactivation. Theragun Percussive Therapy Group (TG) (Skinner et al., Electrical Muscle Stimulation Power Dot Group (PD) (Sañudo et al., Therabody Pneumatic Compression Boot group (COMP) (Nuell et al., Upon completion of their assigned interventions, participants immediately returned to the testing location for completion of the second half performance. This was repeated identically as described above. |
| Statistical analysis |
Analyses were conducted in RStudio (v2024.09.0+375) using linear mixed-effects models (LMMs) via the lmerTest package. Outcome variables included sprint time, HR, LSPT metrics, and TQR. Fixed effects were Time (first vs. second half), Condition (CON, TG, PD, COMP), and their interaction. A random intercept for 'Participant' was included to account for the nested structure of the repeated measures (First Half vs. Second Half) and to control for the inherent inter-individual variability in baseline technical skill and physical capacity. The primary focus was the Time × Condition interaction to assess intervention effects on second-half performance. Significance was set at p = .05. To control for the increased risk of Type I errors associated with multiple outcome measures and post-hoc comparisons, a Bonferroni-Holm adjustment was applied to all p-values. This ensures that the cumulative alpha level across the study remains at 0.05, providing a conservative and rigorous threshold for claiming statistical significance. Post hoc comparisons used estimated marginal means (EMMs), with Cohen’s d calculated for effect size. Standardized mean differences (Cohen’s d) were calculated to quantify the magnitude of the intervention effects. To ensure a conservative and stable estimate, d was standardized using the pooled baseline (First Half) standard deviation rather than model-based residuals. Confidence intervals (95% CI) were calculated for both the raw interaction estimates and the standardized effect sizes to illustrate the precision of the observed effects and their practical relevance to elite soccer performance. Both performance improvements and reduced declines were considered beneficial. Data visualizations were created using ggplot2, and descriptive statistics (means ± SD) are reported for all outcomes. |
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To ensure the study was adequately powered to detect meaningful changes in performance, an a priori power analysis for a 4 (Condition) x 2 (Time) interaction was conducted. Based on an alpha of 0.05 and a power of 0.80, a minimum sample of n = 36 was required to detect a medium effect size (f = 0.25). Our final enrollment of n = 43 participants satisfies this requirement and provides sufficient degrees of freedom to rigorously estimate individual-level variance in our Linear Mixed-Effects Models (LMMs). This sample size, combined with the use of LMMs, ensures sensitivity to detecting nuances in halftime intervention efficacy. |
| Loughborough Soccer Pass Test (LSPT) |
The mean percent change was calculated for all groups, and a decrease in the overall LSPT score indicated better performance. The overall LSPT score increased for CON (7.47%) and COMP (1.77%), indicating deterioration. The overall LSPT score decreased for TG (-2.43%) and PD (-2.55%), indicating improved performance. There was a significant main effect of Time, b = 4.68, SE = 1.49, t (39) = 3.14, p = 0.003, indicating a deterioration in performance from first to second half in the CON group. There were no main effects of conditions; all groups saw similar performance in the first half as the CON group. There was a Time × Condition interaction were found for PD group (b = -6.22, SE = 2.25, t(39) = -2.77, p = 0.009, d = 0.39) and (TG group: b = -6.30, SE = 2.31, t(39) = -2.73, p = 0.010, d = 0.41), these groups had less deterioration in performance than the control group in the second half. See For subscale speed, there was a Main effect of Time, b = 1.97, SE = 0.67, t(39) = 2.93, p = 0.006, with CON deteriorating. Time × Condition interaction for PD approached significance (b = -1.96, SE = 1.01, t (39) = -1.94, p = 0.060, d = 0.10), showing less deterioration. For subscale penalties, there was a Main effect of Time, b = 2.71, SE = 1.10, t (39) = 2.46, p = 0.018 (increase in CON). Main effect of Condition for TG, b = 5.61, SE = 2.06, t (55) = 2.73, p = 0.009 (higher baseline penalties). Time × Condition interactions indicated smaller increases for PD (b = -4.26, SE = 1.66, t (39) = -2.56, p = 0.014, d = 0.53) and TG (b = -6.31, SE = 1.71, t (39) = -3.70, p < 0.001, d = 1.23). |
| Heart rate during sprint performances |
| Total Quality of Recovery (TQR) |
Mean percent change was calculated for all groups, and higher TQR indicated a better perceived recovery. The TQR decreased in all groups: CON (32.5%), TG (18.9%), PD (12.6%), and COMP (9.93%). A significant main effect of Time, b = -5.36, SE = 0.39 t(39) = -13.79, p < .001, indicating that TQR scores decreased significantly from the first to the second half the CON group. No main effects of conditioning, indicating all group were similar in the first half. Time × Condition interactions were observed in all intervention groups, COMP: b = 3.61, SE = 0.64, t(39) = 5.60, p < .001 d = 1.70, PD: b = 3.18, SE = 0.59, d = 2.12, t(39) = 5.42, p < .001, and TG: b = 2.06, SE = 0.60, t(39) = 3.42, p = 0.0015, d = 3.21. The decrease in TQR was less pronounced in all interaction groups compared to the control (see |
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This study aimed to examine whether a range of half-time passive interventions could mitigate reduction in simulated soccer match performance in elite academy-level male soccer players. The results of the present study confirmed previous work in that passive half-time rest resulted in deterioration in technical performance, sprint performance whilst increasing cardiovascular response, and perceived recovery. The main finding was that all three applied interventions attenuated decline in at least one performance or perceptual outcome. This supports the premise that half-time represents a modifiable window for performance preservation rather than a period of performance loss as seen in previous literature; (Lovell et al., Consistent with prior work, we observed second-half decrements following passive half-time rest (Abade et al., TG exhibited the most consistent performance of protective interventions across measured outcomes. When compared with CON, the TG group showed reduced deterioration in overall LSPT performance (time + penalties), smaller worsening of 20-m sprint time, a smaller rise in heart rate, and a smaller drop in TQR. Practitioners should interpret halftime TQR scores as vital measures of an athlete's cognitive readiness and subjective willingness to compete, noting that this perceptual state can occasionally decouple from objective physical and technical performance outputs. Previous work indicates that PT can acutely influence local tissue compliance and perceived muscle readiness without impairing force production, which may support repeated high-intensity and technical actions under fatigue (Sams et al., The EMS condition showed reduced deterioration in overall LSPT performance and penalties (e.g., passing to the wrong target) and a smaller reduction in TQR, but no clear advantage in short sprint performance relative to CON. This pattern is consistent with the broader EMS literature in which low-frequency EMS can facilitate blood flow enhancement and metabolite clearance even when effects on sprinting are inconsistent across protocols and populations (Babault et al., COMP did not meaningfully alter LSPT outcomes but did attenuate deterioration in average 20-m sprint performance and produced the smallest decline in TQR among interventions. Single sessions of COMP lasting 30 minutes commonly show perceptual benefits, even when immediate performance effects are mixed (Ferrer-Ramos et al., Collectively, the findings of the present study indicate that half-time passive interventions can exert perceptual, physical, and technical performance outcome-specific effects rather than uniformly enhancing every domain. Interventions that preserved technical performance (TG, EMS) also attenuated decrements in perceived recovery, whereas sprint preservation appeared with percussive therapy and pneumatic compression in the present study. Importantly, none of the modalities impaired second-half outcomes, supporting feasibility and safety for applied half-time use. A practical consideration in half-time implementation is the need to prioritize coach-led tactical and technical communication alongside established hydration and nutritional strategies. The interventions examined in the present study were passive, required little additional physical exertion, and were self-administered within the existing half-time duration. Consequently, these interventions can be deployed concurrently during the half-time period alongside coaching instruction, minimizing interference with tactical delivery or increasing physical load. This may be relevant in professional environments where half-time routines are tightly structured, and interventions that compete with coaching priorities are unlikely to be adopted. The present findings indicate that passive half-time interventions may function as adjuncts within existing half-time processes rather than displacing technical, tactical, or nutritional practices. These strategies are intended to complement, not replace, efficacious half-time practices such as short re-warm-ups or heat maintenance, which have demonstrated benefits for second-half outputs (Abade et al., Based on these findings, we propose an outcome-driven decision framework for practitioners: if the primary halftime priority is preserving technical passing precision and composure, percussive therapy (TG) or electrical muscle stimulation (PD) should be deployed; conversely, if maintaining explosive sprint capacity or maximizing acute perceptual recovery is paramount, percussive therapy or pneumatic compression (COMP) should be selected. However, as these technologies were evaluated strictly as isolated, standalone interventions, coaches must apply them with caution. Despite the significant findings, several limitations must be acknowledged. First, while the total sample size (n = 43) was sufficient for the primary analysis, the per-group sample size is relatively small, which may limit the generalizability of the findings to larger, more diverse populations of soccer players. Second, the nature of the physical interventions precluded the blinding of participants to their assigned conditions; therefore, the potential for expectancy effects cannot be entirely ruled out. The absence of a sham-control condition means we cannot definitively isolate the physiological effects from the psychological perception of having received an intervention. However, in the context of elite academy soccer, using a true 'sham' is often impractical and may compromise the ecological validity of the halftime environment. The study utilised a simulated soccer protocol rather than competitive match play, which may limit ecological validity given the absence of tactical, opponent, psychological, and contextual influences inherent to competition. In addition, no direct physiological or mechanistic measures were collected; therefore, interpretations are limited to observed performance and perceptual outcomes rather than to underlying biological responses to the interventions. Additionally, because tissue temperature was not directly tracked in the present study, temperature changes remain a candidate physiological mechanism rather than a definitive driver of our observed outcomes. |
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Passive half-time interventions can attenuate the expected decline in second-half physical and technical performance in elite academy soccer players. Passive halftime interventions offer a practical means of attenuating performance decline in elite academy soccer, though the benefits are modality-specific. Percussive therapy and EMS were most effective in preserving technical performance, whereas pneumatic compression supported sprint performance stability and perceived recovery. Notably, none of the modalities significantly enhanced heart rate recovery, and improvements in sprint performance were localized primarily to the percussive therapy group. These portable modalities offer a pragmatic solution for practitioners to maintain player readiness in congested locker room environments where space for active re-warm-ups is limited and tactical briefings remain the priority. Practitioners should, therefore, select halftime interventions based on the specific physiological or technical priorities of the player and the preceding match demands, rather than viewing these tools as universally effective across all performance domains. These findings provide applied options for half-time performance preservation in academy-level soccer and can complement existing re-warm-up protocols. |
| ACKNOWLEDGEMENTS |
The experiments comply with the current laws of the country where they were performed. Informed consent was obtained from the parents or legal guardians of all minor participants prior to their involvement in the study. Assent was also obtained from the minors in accordance with ethical guidelines for research involving children. The authors are employees of or contractors for Therabody, a company that develops and markets products related to recovery and performance. This affiliation may be perceived as a potential conflict of interest, as Therabody could benefit from the publication and dissemination of this research. No other financial interests or relationships influenced the conduct or reporting of this study. Therabody provided product support for this study in the form of (recovery devices). No direct financial compensation was received by the first author, Brendon Skinner. Therabody had no role in the study design, nor data collection. The data collected and analysis for this study is available upon request to the corresponding author. The authors declare that no Generative AI or AI-assisted technologies were used in the writing of this manuscript. |
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