Effect of weighted sled towing on sprinting effectiveness, power and force-velocity relationship

Pantoja, Patrícia Dias; Carvalho, Alberito Rodrigo de; Ribas, Leonardo Rossato; Peyré‐Tartaruga, Leonardo Alexandre

doi:10.1371/journal.pone.0204473

Cited by 19 publications

(19 citation statements)

References 33 publications

(64 reference statements)

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“…For example, previous studies used radar (Cross et al, 2015), photocells (Samozino et al, 2016;Romero-Franco et al, 2017), linear encoders (Cross et al, 2018), or high-speed video (Romero-Franco et al, 2017) after verification of the high-quality of fitting (correlation coefficient >0.99). In addition, this almost perfect fit was observed in loaded sprint conditions (Pantoja et al, 2018;Cross et al 2017b;Cross et al 2018) and for various levels of sprint performance and athletes' age and sex (Pantoja et al, 2016;Slawinski et al, 2017;Nagahara et al, 2017b), which tends to support its general validity to varying athlete's characteristics/levels and with external resistance. However, if high-quality exponential fitting of the data is not verified preceding analysis, any subsequent computations might lead to inaccurate data and conclusions (e.g.…”

Section: Discussionmentioning

confidence: 64%

A simple method for computing sprint acceleration kinetics from running velocity data: Replication study with improved design

Morin

Samozino

Murata

et al. 2019

Journal of Biomechanics

111

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Measuring the ground reaction forces (GRF) underlying sprint acceleration is important to understanding the performance of such a common task. Until recently direct measurements of GRF during sprinting were limited to a few steps per trial, but a simple method (SM) was developed to estimate GRF across an entire acceleration. The SM utilizes displacement-or velocity-time data and basic computations applied to the runner's center of mass and was validated against compiled force plate (FP) measurements; however, this validation used multiple-trials to generate a single acceleration profile, and consequently fatigue and error may have introduced noise into the analyses. In this study, we replicated the original validation by comparing the main sprint kinetics and force-velocity-power variables (e.g. GRF and its horizontal and vertical components, mechanical power output, ratio of horizontal component to resultant GRF) between synchronized FP data from a single sprinting acceleration and SM data derived from running velocity measured with a 100 Hz laser. These analyses were made possible thanks to a newly developed 50-m FP system providing seamless GRF data during a single sprint acceleration. Sixteen trained male sprinters performed two all-out 60-m sprints. We observed good agreement between the two methods for kinetic variables (e.g. grand average bias of 4.71%, range 0.696±0.540-8.26±5.51%), and high inter-trial reliability (grand average standard error of measurement of 2.50% for FP and 2.36% for the SM). This replication study clearly shows that when implemented correctly, this method accurately estimates sprint acceleration kinetics.

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Section: Discussionmentioning

confidence: 64%

A simple method for computing sprint acceleration kinetics from running velocity data: Replication study with improved design

Morin

Samozino

Murata

et al. 2019

Journal of Biomechanics

111

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“…In recent years, a simpler kinematic approach has been developed for power output computation during accelerated running . It considers the time course of a runner's velocity that can be easily measured by laser‐assisted or other time/gate devices . From the time course of BCoM velocity of our subjects, we also computed the horizontal power as proposed by Samozino et al (a) by fitting the time course of the subject's velocity with a mono‐exponential equation, which was (b) time differentiated to obtain acceleration and (c) by multiplying acceleration and velocity, mass‐specific power was obtained (W kg −1 ), (d) the mean of which was considered as horizontal power ( P horizontal ) and compared with our values (Figure ).…”

Section: Discussionmentioning

confidence: 99%

Comprehensive mechanical power analysis in sprint running acceleration

Pavei

Zamparo

Fujii

et al. 2019

Scandinavian Med Sci Sports

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Sprint running is a common feature of many sport activities. The ability of an athlete to cover a distance in the shortest time relies on his/her power production. The aim of this study was to provide an exhaustive description of the mechanical determinants of power output in sprint running acceleration and to check whether a predictive equation for internal power designed for steady locomotion is applicable to sprint running acceleration. Eighteen subjects performed two 20 m sprints in a gym. A 35‐camera motion capture system recorded the 3D motion of the body segments and the body center of mass (BCoM) trajectory was computed. The mechanical power to accelerate and rise BCoM (external power, Pext) and to accelerate the segments with respect to BCoM (internal power, Pint) was calculated. In a 20 m sprint, the power to accelerate the body forward accounts for 50% of total power; Pint accounts for 41% and the power to rise BCoM accounts for 9% of total power. All the components of total mechanical power increase linearly with mean sprint velocity. A published equation for Pint prediction in steady locomotion has been adapted (the compound factor q accounting for the limbs' inertia decreases as a function of the distance within the sprint, differently from steady locomotion) and is still able to predict experimental Pint in a 20 m sprint with a bias of 0.70 ± 0.93 W kg−1. This equation can be used to include Pint also in other methods that estimate external horizontal power only.

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“…The ICC for both resistance levels and both distances were very large and nearly perfect which were similar to other resisted sprint studies (range 0.79-0.98). Pantoja et al (2018) reported similar reliability values during sled towing with a group of international, national and regional sprint athletes (ICC = 0.87-0.94). Bachero-Mena and González-Badillo (2014) studied the effects of three different sled loads on acceleration in male, physically active participants (5%, 12.5% and 20% of body mass).…”

Section: Discussionmentioning

confidence: 55%

“…However, times for the sprints were measured using a stopwatch with no reported reliability. A recent study by Pantoja, Carvalho, Ribas and Peyré-Tartaruga (2018) highlighted the effect of sled towing (20, 30 and 40% of body mass) on sprint time, power and the force-velocity relationship using international, national and regional level athletes. With the greatest load, the end of the acceleration phase VOLUME --| ISSUE -| 2020 | 3 was significantly greater compared to all other loads (ES = 2.22-3.25; p<0.001).…”

Section: Introductionmentioning

confidence: 99%

Intra and intersession reliability of the Run RocketTM in recreationally trained participants

Godwin¹,

Matthews²,

Stanhope³

et al. 2020

jhse

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Sprint performance plays an important role in the success of many sports including track and field and teambased sports. Resisted sprint equipment has shown to be an effective method to increase sprint velocity and acceleration. The aim of the study was to determine the intrasession and intersession (7 days) reliability of a commercially available resisted sprint machine in recreationally trained individuals for two resistance settings. Fourteen recreationally active participants partook in the study (male = 10, female = 4) over a 7-day period. Three maximal 15m sprints, at two resistance levels (R0 and R5), were undertaken in a randomised order (6 sprints in total at each trial). Intrasession (comparison of the first 3 sprints for each trial) and intersession (mean of the 3 sprints for both trials) correlation coefficient (ICC), coefficients of variation (%CV), average variability, SEM and minimal detectable difference were calculated for 5 and 15m for both resistance levels. Intrasession reliability was very large to nearly perfect across both distances and resistance levels (ICC range 0.79-0.98), %CV ranged between 2.4-5.8% with larger values seen during the first trial for three of the four indices. Intersession reliability was very large to nearly perfect across all variables (ICC range 0.87-0.97), %CV was small and ranged between 2.0-4.1%. Average variability was small for all measurements. The Run Rocket TM showed high intra and intersession reliability. The results show that this equipment could be reliably used within a sprint programme for recreationally trained individuals. VOLUME --| ISSUE -| 2020 | 7 AUTHOR CONTRIBUTIONSConceptualization, M.G. and E.S.; Methodology and Investigation, M.G., J.M., E.S. and K.R.; Data analysis, M.G.; Writing-original draft preparation, M.G.; writing-review and editing, M.G., J.M., E.S. and K.R.

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Effect of weighted sled towing on sprinting effectiveness, power and force-velocity relationship

Cited by 19 publications

References 33 publications

A simple method for computing sprint acceleration kinetics from running velocity data: Replication study with improved design

A simple method for computing sprint acceleration kinetics from running velocity data: Replication study with improved design

Comprehensive mechanical power analysis in sprint running acceleration

Intra and intersession reliability of the Run RocketTM in recreationally trained participants

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