The use of wearable resistance and weighted vest for sprint performance and kinematics: a systematic review and meta-analysis

Wearable resistance (WR) and weighted vests (WV) can be used in almost all training conditions to enhance sprint performance; however, positioning and additional mass are different in WV and WR strategies, affecting performance and kinematics differently. We aimed to systematically review the literature, searching for intervention studies that reported the acute or chronic kinematic and performance impact of WV and WR and comparing them. We analyzed Pubmed, Embase, Scopus, and SPORTDiscuss databases for longitudinal and cross-over studies investigating sprint performance or kinematics using an inverse-variance with a random-effect method for meta-analysis. After the eligibility assessment, 25 studies were included in the meta-analysis. Cross-over WR and WV studies found significantly higher sprint times and higher ground contact times (CT) compared to unloaded (UL) conditions. However, WR presented a lower step frequency (SF) compared to UL, whereas WV presented a lower step length (SL). Only one study investigated the chronic adaptations for WR, indicating a superiority of the WR group on sprint time compared to the control group. However, no difference was found chronically for WV regarding sprint time, CT, and flight time (FT). Our findings suggest that using WV and WR in field sports demonstrates overload sprint gesture through kinematic changes, however, WR can be more suitable for SF-reliant athletes and WV for SL-reliant athletes. Although promising for chronic performance improvement, coaches and athletes should carefully consider WV and WR use since there is no supporting evidence that WV or WR will impact sprint performance, CT, and FT.


Selection and data collection process
The search results were uploaded to Rayyan Software 22 .Firstly, the duplicates were identified automatically (https:// www.rayyan.ai/).Two independent authors (GFAB and IAS) conducted the initial screening for the title and abstract based on the PICOT strategy.The articles selected were read in full.Articles that met all the eligibility criteria were included.The first search was performed on 05/11/2022 and then updated on 08/30/2023.

Data items
The included articles were first separated into WR or WV interventions to compare both conditions.Then, cross-over and longitudinal studies were separated for further subgroup analysis in WR loads (≤ 2%; > 2%), WR placement (upper body; lower body), and sprint phase (acceleration; maximum velocity).
For the studies that did not report the WR/WV load in % of BM, the load was normalized by the average BM of the sample.Acceleration and maximum sprint phases were defined as equal or less than 30 m and more than 30 m, respectively 20,23 .The variables of interest were kinematic data, sprint time, sample size, age, height, BM, training experience, best sprint performance, study design, ability level, study intervention, objective, sprint test, WR/WV load and placement.

Study risk of bias and quality assessment
Two independent authors (IAS and MFTJ) assessed the quality of the included articles using the Physioterapy Evidence Database (PEDro) tool.The tool is composed of eleven criteria.Each criterion satisfied received 1 point (except for the first criterion).Articles scoring six to ten were considered high quality; scores between four and five were considered moderate quality; scores lower or equal to three were considered low quality.A senior author resolved discrepancies among authors (EFP).The publication bias was assessed visually from funnel plots for two authors independently (IAS and MFTJ); more asymmetry from the vertical axis can indicate publication bias 24 .

Effect measures and synthesis methods
All analyses were conducted in the software Review Manager 5.3.An inverse-variance with a random-effect method was used.For longitudinal studies, the mean for the experimental and CON group was calculated based on the mean difference of the post-intervention value minus the pre-intervention value.The standard deviation was calculated from the pooled standard deviation of change scores in both groups by using a correlation value of 0.5 and the formula described SD E,change = SD 2 E,baseline + SD 2 E,final − 2 X Corr XSD E,baseline X SD E,final in the Cochrane Handbook for Systematic Reviews of Interventions 25 .For cross-over studies, authors used the mean and SD of the sample in the loaded condition as experimental mean and SD, and the same was done for the UL condition as control mean and SD.Only the total time of the performance tests was used (the split times were not considered) avoiding inflate the meta-analysis.In addition, the thigh outcome was chosen for the WR studies in which the effect of using the thigh or shank WR was verified, as it is the most common.The highest weight reported was considered for studies where more than one weight for WV and WR were tested.After that, the included studies were separated by intervention period (cross-over or longitudinal).Then, the following subgroup analysis was conducted for WR cross-over interventions: loads (≤ 2%; > 2%), placement (upper body; lower body) and sprint phase (acceleration; maximum velocity).Due to the lack of data, subgroup analyses were not done for WR and WV longitudinal interventions.The confidence interval used was 95% for a random effect model.For the heterogeneity analyses, the I 2 test was used.The P ≤ 0.05 was considered statistical significance, and I 2 > 50% indicated high heterogeneity.

Study selection
Initially, 1975 studies were returned following the search strategy.On Embase, 401 studies were identified, 749 on Scopus, 405 on SPORTDiscuss, and 420 on PubMed.The authors removed 943 studies considered duplicates, resulting in 1032 studies included for the title and abstract screening.Of the 1032 records screened, 985 were considered ineligible, resulting in 47 studies in the last screening process.From the 47 studies read in full, one was excluded because only the abstract was published, one study was not accessible, eight studies did not involve WR or WV, four studies did not provide sufficient data to be included in the meta-analysis, four studies did not include maximal sprint tests, three studies were based on youth sample, and one study did not include a CON group.Thus, 25 studies were included in the systematic review and meta-analysis [10][11][12][13][14][15][16][17][18][19][20][21]23,[27][28][29][30][31][32][33][34][35][36][37][38] . Figure 1shows the study selection process.
No sub-group analysis demonstrated significance for flight time.
No sub-group analysis demonstrated significance for step length.Study characteristics and subgroup analysis for WR cross-over intervention are presented in Electronic Supplementary Material (Figure S14 to S27 and Table S1, respectively).www.nature.com/scientificreports/
Sprint performance WV.Results in meta-analysis indicated a significantly lower sprint time for UL condition ([SMD] 2.33 (95% CI 1.66 to 3.00), Z = 6.82 (p < 0.01)) with a low, non-significant, average heterogeneity (I 2 = 5% (p = 0.35)).The forest plot for meta-analysis is presented in Fig. 7. Three studies reported the sprint time 11,28,37 with a 2.52 to 16.63% higher sprint time in the WV condition compared to the UL condition.Of those, only one study reported the ES for sprint time 11 , ranging from moderate to very large.   .The forest plot for meta-analysis is presented in Fig. 8. Three studies reported the ground contact time 12,28,30 with a 1.35 to 24.32% higher ground contact time in the WV condition compared to the UL condition.Of those, two studies reported the ES for ground contact time 12,30 , ranging from 0.70 to 1.71.
Flight time WV.Results in meta-analysis indicated a non-significant difference between the WV condition and UL condition for flight time ([SMD] − 0.49 (95% CI − 1.16 to 0.19), Z = 1.41 (p = 0.16)) with a low, nonsignificant, average heterogeneity (I 2 = 10% (p = 0.29)).The forest plot for meta-analysis is presented in Fig. 9. Two studies reported the flight time 12,30 with a − 1.67 to − 27% lower flight time in the WV condition compared to the UL condition.ES for flight time 12,30 ranged from − 0.28 to − 1.50.
Step frequency WV.Results in meta-analysis indicated a non-significant difference between the WV condition and UL condition for step frequency ([SMD] − 0.45 (95% CI (− 1.03) to 0.13), Z = 1.51 (p = 0.13)) with a low, nonsignificant, average heterogeneity (I 2 = 0% (p = 0.71)).The forest plot for meta-analysis is presented in Fig. 10.Three studies reported the step frequency 12,28,30 with a percentual change ranging from 0.72 to − 4.89% in the UL condition compared to the WV condition.Of those, only one study reported the ES for step frequency 12,30 , ranging from − 0.17 to − 0.34.
Step length WV.Results in meta-analysis indicated a significantly lower step length for WV condition ([SMD] − 0.70 (95% CI (− 1.30) to (− 0.09)), Z = 2.27 (p = 0.02)) with a low, non-significant, average heterogeneity (I 2 = 0% (p = 0.38)).The forest plot for meta-analysis is presented in Fig. 11.Three studies reported the step length 12,28,30 with a − 1.95 to − 10.81% lower step length in the WV condition compared to the UL condition.Of those, two studies reported the ES for step length 12,30 , ranging from − 0.33 to − 0.55.The Electronic Supplementary Material (Table S2) presents study characteristics for WV cross-over intervention.

Longitudinal WR interventions
Only one study conducted a longitudinal design with a WR intervention 15 .A 1% BM load was applied to the shank.The sprint test used for performance assessment was 30-m.Sprint performance WR.Results for sprint time on pre-post intervention in the WR group ranged from 0.22 to 1.59%, and pre-post intervention in the CON group ranged from 2.20 to 7.87%.ES varied from 0.06 to 0.29 in pre-post intervention in the WR group, whereas ES varied from 0.36 to 1.25 in the CON group.
The Electronic Supplementary Material (Table S3) presents study data for WR longitudinal intervention.

Longitudinal WV interventions
Four studies presented a longitudinal design with a WV intervention 10,18,19,35 .Loads applied varied from 8 to 18.9% of the sample BM 10,18,19,35 .Sprint test distance varied between 10-to 54.9 m.There was no difference in frequency concerning the load and sprint test used between the studies.
Sprint performance WV.Results in meta-analysis indicated no difference in sprint time between groups ([SMD] − 0.02 (95% CI (− 0.51) to 0.46), Z = 0.10 (p = 0.92)) with a low, non-significant, average heterogeneity (I 2 = 0% (p = 0.94)).The forest plot for meta-analysis is presented in Fig. 12.All studies reported the sprint time 10,18,19,35 with a 0 to − 9.55% change in sprint time in pre-post intervention for the WV group and a 0 to − 11.17% change in sprint time in pre-post intervention for the CON group.Three studies reported ES 10,18,19 ,   www.nature.com/scientificreports/varying from 0 to 3.30 in pre-post intervention in the WV group, whereas ES varied from 0 to 2.50 in the CON group.
Ground contact time WV.Results in meta-analysis indicated no difference in ground contact time between groups ([SMD] − 0.34 (95% CI (− 1.52) to 0.83), Z = 0.57 (p = 0.57)) with a high, non-significant, average heterogeneity (I 2 = 57% (p = 0.13)).The forest plot for meta-analysis is presented in Fig. 13.Two studies reported the ground contact time 10,18 with a 0 to − 9.09% change in ground contact time in pre-post intervention for the WV group and a 0 to − 3.79% change in pre-post intervention for the CON group.Two studies reported ES 10,18 varying from 0.09 to 0.28 in pre-post intervention for the WV group, whereas ES varied from 0.1 to 0.38 in the CON group.
The forest plot for meta-analysis is presented in Fig. 14.Two studies reported the flight time 10,18 with a − 5.40 to 9.09% change in pre-post intervention for the WV group and a 0 to 9.09% change in pre-post intervention for the CON group.Two studies reported ES 10,18 varying from 0.25 to 1.00 in pre-post intervention in the WV group, whereas ES varied from 0 to 0.40 in the CON group.The Electronic Supplementary Material (Table S4) presents study characteristics for WV longitudinal interventions.

Discussion
WR and WV are loaded sprint strategies that can be implemented during training, aiming for higher performance.Due to the differences in weight and positioning used between the WV and WR, different adaptations can be found with its use.Thus, we aimed to systematically review the literature and conduct a meta-analysis on the acute and chronic kinematic and performance impact of WV and WR, comparing them.The acute findings involve: (1) WR and WV produced an increased sprint time compared to UL. Subgroup analysis also demonstrated an increase in sprint time in the acceleration sprint phase for WR condition and with WR loads ≤ 2% BM compared to UL; (2) WR and WV produced an increased ground contact time compared to UL. Subgroup analysis also demonstrated an increase in ground contact time in the acceleration sprint phase for WR condition, with WR loads ≤ 2% BM, and for WR placed in the lower body compared to UL; (3) WR produced a lower step frequency compared to UL. Subgroup analysis also demonstrated a decrease in step frequency on acceleration sprint phase for WR condition, with WR loads ≤ 2% BM, and for WR used in the upper body compared to UL; (4) WV produced a lower step length compared to UL.The main finding for longitudinal studies was: 1) The WR group maintained sprint time compared to the CON group, which decreased the sprint time.Figure 15 represents an infographic about acute kinematic changes for WR and WV.
Both WR and WV demonstrated an increase in sprint time, as shown in the meta-analysis.Sprinting with additional load can be challenging as the additional load offers resistance to the movement, decreasing the velocity 7 and, consequently increasing the sprint time.In addition to WV and WR, other strategies to overload the sprint movement are used in the field.Alcaraz et al. 7 found a 5 to 6% velocity decrease with a parachute and a 12 to 14% velocity decrease with sled towing.Compared to the results of this meta-analysis, the 5 to 6% performance loss in the parachute condition is close to the performance loss found in the WR condition (i.e., 0 to 7.4%).Conversely, 12 to 14% of performance lost in sled towing conditions are closer to WV condition in this  www.nature.com/scientificreports/meta-analysis (i.e., 2.52 to 16.63%).The loss in performance can be explained by the additional load used.In sled towing conditions, loads were approximately 16% of BM.Such load is much heavier than the loads used in WR studies (i.e., 0.55 to 5%).Probably, the parachute size used was not enough to largely reduce the performance, as seen in WV condition.On the other hand, Alcaraz et al. 7 also investigated the effects of a weight belt (a very similar strategy to the WV) in sprinting, finding a reduction of 3% in sprint velocity.A 3% loss in performance is very similar to the lowest performance reduction found for WV in this meta-analysis (i.e., 2.52%).This reduction is reasonable as the load in the weight belt condition (9%) was close to the minimum load used in WV studies (7%).Therefore, the more load used, the more overload is promoted during sprint 7,11,39 ; however, in our sub-analysis, sprinting with ≤ 2% of the BM demonstrated superiority in reducing sprint time compared to > 2% of the BM.Sprinting with WR can increase the rotational inertia of the limbs as additional resistance is added, beginning with 2.42% more inertia with 200 g and reaching 11.04% more inertia with 1000 g 9 .Thus, the higher rotational inertia from higher loads may have contributed to less impact on sprint time, ground contact time, and step length as an assistant to the swing phase during sprinting.Regarding ground contact time, athletes have little time in contact with the ground during sprinting to generate force to move (i.e., ~ 0.1 to 0.2 s) 17,20 .Thus, the more force athletes can apply during every contact can result in better performance 40 .As a result of carrying more load due to WV or WR strategies, athletes need to spend more time during the contact to produce a similar amount of propulsive force 17,28,34 .Not only WV and WR but also the use of external load in resistive sprint techniques constantly demonstrate an increase in ground contact time 28,41 .During the acceleration phase, the ground contact time is higher, compared to the maximal velocity phase, as athletes needed more time to produce the necessary force 42 and overcome inertia.In this context, the results from this meta-analysis confirm that the acceleration phase experienced higher ground contact time using WR and, thus, a higher sprint time.A greater horizontal force is needed in the acceleration phase compared to the maximum velocity phase to overcome inertia during sprint initiation, resulting in a higher propulsive impulse 42 , especially with additional load.Unlike ground contact time, flight time does not seem to change during an loaded sprint.An unchanged flight time seems a constant outcome even during other loaded/resistive strategies, like sled and parachute, irrespective of the load 43,44 .However, to maintain flight time constant, athletes must apply more force on the ground, as shown with increased electromyography for lower limb muscles, associated with a higher ground contact time 44 , ensuring a propulsion similar to UL condition, with little change on flight time.
The meta-analysis results demonstrated a significant decrease in step frequency for WR and step length for WV.Step frequency and step length are related and determinants of the final velocity (i.e., Velocity = step frequency × step length).Thus, if an athlete's performance is affected, one or both step kinematics will also be affected.Therefore, one reason to explain the decreased sprint time on the WR condition is the decreased step frequency, whereas the decreased sprint time on WV is due to a decreased step length.During sprinting, higher times to complete a full stride cycle (ground contact time + flight time) will negatively influence the number of steps an athlete completes (step frequency) 34,45 .This explains why step frequency decreases in the WR condition as the ground contact time increases.
Conversely, if an athlete covers short distances at each step, as seen in WV with a decreased step length, there is a necessity for a higher number of steps.Even though the higher number of steps was not large enough to demonstrate significance on step frequency for the WV condition, it affected sprint time.Elite athletes' reliance on respecting step length or step frequency is very individual 46 .Thus, we recommend step frequency-reliant athletes choose WR for their training programs (especially, but not constantly, for upper body and ≤ 2% BM WR), whereas step length-reliant chose the WV strategy.
During sprinting, leg and arm coordination is important in improving performance 47 ; however, there is a slight difference between the lower and upper limbs' contributions to propulsion during sprinting.The upward movement of the arms causes a downward force on the body that contributes to a larger force being applied to the ground and generating a larger impulse 48 .Using WR in forearms can overload arm swing, generating more vertical impulse 21 .Thus, although arms play an important role in maintaining balance, they also contribute to lower limbs' sprint performance 49 , especially in the start and acceleration phases, where the body presents a more leaning position 47 .Sub-group analysis demonstrates a significantly increased ground contact time for WR's lower body and decreased step frequency for WR's upper body conditions.Couture et al. 50found an increased ground contact time with upper and lower body WR (except for 1% lower body WR), yet with no significance compared to UL.However, the authors found that during the lower body condition, the horizontal propulsive impulse increased twofold compared to the upper body condition, although both conditions demonstrated, in part, increased propulsive force compared to the UL condition.Thus, the more propulsive force needs higher ground contact time, explaining why lower body WR increased the contact time.Since more ground contact time is demanded from lower body WR, the authors expected that the step frequency would also present a significant decrease in the WR in the lower limbs, which did not occur.Only upper-body WR showed a lower step frequency.We believe that the greater presence of studies that evaluated the step frequency in the maximum velocity phases in sub-group analysis for the lower body compared to the sub-analysis for the upper body may have masked the effects since the acceleration phase demands more ground contact time.
The kinematic changes in acute interventions using WV and WR raise questions about long-term adaptations.Meta-analysis results indicate no difference between CON ground and WV group, however, with WR presenting a beneficial effect in maintaining a better sprint time, compared to the decreased sprint time in the CON group.The studies included in this meta-analysis with long-term use of WV demonstrated significant improvement in sprint performance after a training period, regardless of the condition (loaded or unloaded sprint) 18,19 .Highintensity sprint training positively influences muscle fiber type shift, enhances stretch reflex (increasing force production), and increases the capability to produce maximal forces [51][52][53] , thus increasing performance.Therefore, positive muscle adaptations are not necessarily greater using WV, considering sprint training.
On the other hand, in the only study analyzing long-term WR training, authors found a better result in performance with WR when compared to CON 15 .However, even in the WR group, there was no pre-and post-performance enhancement.What happened is that the WR group lost less performance during the study period than the CON group, showing a significant difference between the groups post-training.Still, only one study investigated WR.Therefore, the additional load does not bring benefits beyond the training stimulus itself.
Initially, a question was raised about the efficiency of the vertical overload applied by WV and WR, which is different from horizontal overload from sled towing, for example.However, Alcaraz et al. 54 drew similar conclusions with sled towing training to improve performance.Nonetheless, Alcaraz et al. 54 sub-group analysis demonstrated a better ES for training periods longer than six weeks.All studies included in this meta-analysis used 6 weeks or less of training period, except for Clark et al. 18 , which used seven.Thus, longer training periods may result in larger benefits from resisted/loaded sprint training.About the load applied, Alcaraz et al. 54 observed a higher effect size and significant improvements with loads lower than 20%.The better results found by Alcaraz et al. 54 with lower load can probably be explained by the loss of sprint technique when higher loads are applied.Some studies, like Clark et al. 18 , used a 10% velocity loss as a determinant to establish the load magnitude.Thus, it is important to control the load magnitude, especially when higher loads are used, to not disturb the athlete's technique excessively.
This meta-analysis demonstrated that long-term WV training did not show any statistical difference from CON in reducing or enhancing ground contact time or flight time.Literature shows that the fastest athletes demonstrate decreased ground contact time compared to their slower counterparts 55 .However, even if studies support that long-term sprint training affects the contact time, it appears to be non-dependent upon overloading techniques used in sprint training 18 .A more efficient force production (and then less contact time) results from sprint training itself.The same partially occurs with Alcaraz et al. 43 , where athletes in UL group significantly reduce the ground contact time in the maximal velocity phase.However, the sled towing group seems to increase the ground contact time, although it is not significant.Like the contact time, flight time presents minimal changes during UL sprint training.Accordingly, Clark et al. 18 demonstrated a moderate decrease in flight time only in WV condition, compared to UL and sled towing, however, with no significant difference.Thus, using WV does not affect long-term ground contact time and flight time, presenting small effects in the sprint technique.

Future perspectives
The acute use of WV and, especially, WR, has been frequently investigated.The main concern about WV and WR is in longitudinal studies.Even if acute interventions demonstrated alterations in kinematic parameters, the low set of evidence until now did not support a higher effectiveness of WV or WR training.More studies are needed to investigate the longitudinal effects of WV and WR, especially above six weeks, and compare different load magnitudes.Specifically, about WR, there are no studies regarding kinematic changes with long-term training.

Limitations
The major limitation of this meta-analysis is the lack of information about longitudinal studies.Care should be taken when interpreting longitudinal conclusions on the use of WR and WV.Yet, only a few studies were considered high-quality.

Conclusions
Using WV and WR in field sports demonstrates overload sprint gestures acutely.Compared to UL conditions, higher ground contact time and sprint time are found with the use of WR and WV during sprinting.However, the use of WR presents lower step frequency, which is more suitable for step frequency-reliant athletes.Conversely, WV presents lower step length, being more suitable for step length-reliant athletes.Although promising for chronic performance improvement, coaches and athletes should carefully consider WV and WR use since there is no supporting evidence that WV or WR will impact sprint performance, ground contact time, and flight times.

Figure 2 .
Figure 2. Forest plot of meta-analysis of the standardized mean difference from WR and UL conditions for sprint time.Ante., Anterior; CI, Confidence interval; SD, Standard deviation; UL, Unloaded condition; WR, Wearable resistance condition.

Figure 3 .
Figure 3. Forest plot of meta-analysis of the standardized mean difference from WR and UL conditions for ground contact time.accel., Acceleration phase; Ante., Anterior; CI, Confidence interval; SD, Standard deviation; UL, Unloaded condition; WR, Wearable resistance condition.

Figure 4 .
Figure 4. Forest plot of meta-analysis of the standardized mean difference from WR and UL conditions for flight time.accel., Acceleration phase; Ante., Anterior; CI, Confidence interval; SD, Standard deviation; UL, Unloaded condition; WR, Wearable resistance condition.

Figure 5 .
Figure 5. Forest plot of meta-analysis of the standardized mean difference from WR and UL conditions for step frequency.accel., Acceleration phase; Ante., Anterior; CI, Confidence interval; SD, Standard deviation; UL, Unloaded condition; WR, Wearable resistance condition.

Figure 6 .
Figure 6.Forest plot of meta-analysis of the standardized mean difference from WR and UL conditions for step length.accel., Acceleration phase; Ante., Anterior; CI, Confidence interval; SD, Standard deviation; UL, Unloaded condition; WR, Wearable resistance condition.

Figure 7 .
Figure 7. Forest plot of meta-analysis of the standardized mean difference from WV and UL conditions for sprint time.CI, Confidence interval; SD, Standard deviation; UL, Unloaded condition; WV Weighted vest condition.

Figure 8 .
Figure 8. Forest plot of meta-analysis of the standardized mean difference from WV and UL conditions for ground contact time.CI, Confidence interval; Max.vel., Maximum velocity; SD, Standard deviation; UL, Unloaded condition; WV, Weighted vest condition.

Figure 9 .
Figure 9. Forest plot of meta-analysis of the standardized mean difference from WV and UL conditions for flight time.CI, Confidence interval; Max.vel., Maximum velocity; SD, Standard deviation; UL, Unloaded condition; WV, Weighted vest condition.

Figure 10 .
Figure 10.Forest plot of meta-analysis of the standardized mean difference from WV and UL conditions for step frequency.CI, Confidence interval; Max.vel., Maximum velocity; SD, Standard deviation; UL, Unloaded condition; WV, Weighted vest condition.

Figure 11 .
Figure 11.Forest plot of meta-analysis of the standardized mean difference from WV and UL conditions for FT.CI, Confidence interval; Max.vel., Maximum velocity; SD, Standard deviation; SL, Step length; UL, Unloaded condition; WV, Weighted vest condition.

Figure 12 .
Figure 12.Forest plot of meta-analysis of the standardized mean difference between WV and CON intervention for sprint time.CI, Confidence interval; CON, Control group; SD, Standard deviation; WV, Weighted vest group.

Figure 13 .
Figure 13.Forest plot of meta-analysis of the standardized mean difference between WV and CON intervention for ground contact time.CI, Confidence interval; CON, Control group; SD, Standard deviation; WV, Weighted vest group.

Figure 14 .
Figure 14.Forest plot of meta-analysis of the standardized mean difference from WV and CON intervention for flight time.CI, Confidence interval; CON, Control group; SD, Standard deviation; WV, Weighted vest group.

Figure 15 .
Figure 15.Acute kinematic change during sprint with WR/WV infographic.CT: Ground contact time; FT: Flight time; SF: Step frequency; SL: Step length; SMD: Standardize mean difference; ST: sprint time.Asterisks denote significant differences compared with the respective UL conditions.