The energy cost of sprint running and the role of metabolic power in setting top performances

Prampero, P. E. di; Botter, Alberto; Osgnach, Cristian

doi:10.1007/s00421-014-3086-4

Cited by 98 publications

(105 citation statements)

References 40 publications

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“…Because the initial upward movement of the CM is overall smoothed through a relative long time/distance (∼30–40 m; Cavagna et al., ; Slawinski et al., ), we can consider that it does not require any large vertical acceleration, and so that the mean net vertical acceleration of the CM over each step is quasi‐null throughout the sprint acceleration phase. Consequently, applying the fundamental laws of dynamics in the vertical direction, the mean net vertical GRF ( F V ) applied to the body CM over each complete step can be modeled over time as equal to body weight (di Prampero et al., ):

F_{normalV} (t) = m \cdot g

where g is the gravitational acceleration (9.81 m/s 2 ).…”

Section: Biomechanical Model Used In the Proposed Methodsmentioning

confidence: 99%

“…Based on the mechanical analyses used in these models, an inverse dynamic approach applied to the runner body center of mass (CM) could give valid estimation of GRF during sprint running acceleration from simple kinematic data, as recently proposed by di Prampero et al. (), but never compared with force plate measurements. This could then be used to obtain the aforementioned sprint mechanical properties without force platform system in typical field conditions of practice.…”

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confidence: 99%

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A simple method for measuring power, force, velocity properties, and mechanical effectiveness in sprint running

Samozino

Rabita

Dorel

et al. 2015

Scandinavian Med Sci Sports

332

605

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This study aimed to validate a simple field method for determining force- and power-velocity relationships and mechanical effectiveness of force application during sprint running. The proposed method, based on an inverse dynamic approach applied to the body center of mass, estimates the step-averaged ground reaction forces in runner's sagittal plane of motion during overground sprint acceleration from only anthropometric and spatiotemporal data. Force- and power-velocity relationships, the associated variables, and mechanical effectiveness were determined (a) on nine sprinters using both the proposed method and force plate measurements and (b) on six other sprinters using the proposed method during several consecutive trials to assess the inter-trial reliability. The low bias (<5%) and narrow limits of agreement between both methods for maximal horizontal force (638 ± 84 N), velocity (10.5 ± 0.74 m/s), and power output (1680 ± 280 W); for the slope of the force-velocity relationships; and for the mechanical effectiveness of force application showed high concurrent validity of the proposed method. The low standard errors of measurements between trials (<5%) highlighted the high reliability of the method. These findings support the validity of the proposed simple method, convenient for field use, to determine power, force, velocity properties, and mechanical effectiveness in sprint running.

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F_{normalV} (t) = m \cdot g

where g is the gravitational acceleration (9.81 m/s 2 ).…”

Section: Biomechanical Model Used In the Proposed Methodsmentioning

confidence: 99%

mentioning

confidence: 99%

A simple method for measuring power, force, velocity properties, and mechanical effectiveness in sprint running

Samozino

Rabita

Dorel

et al. 2015

Scandinavian Med Sci Sports

332

605

View full text Add to dashboard Cite

show abstract

“…This model considers the energetic cost of accelerated running on flat terrain to be equivalent to the known physiological cost of uphill running at a constant pace 8 . Using the acceleration of a player at any time point, an instantaneous energy cost can be estimated.…”

Section: Introductionmentioning

confidence: 99%

“…Using the acceleration of a player at any time point, an instantaneous energy cost can be estimated. This cost can be summated to provide an estimation of overall energy expenditure throughout the activity, or multiplied by velocity, as an indication of metabolic power (Pmet; W·kg -1 ) 8 . Recently, this model has been applied to team sports such amongst professional soccer players, Osgnach et al 9 estimated the distance players would have covered at a constant pace, using the total energy expenditure throughout the match (equivalent distance, ED).…”

Section: Introductionmentioning

confidence: 99%

Acceleration-Based Running Intensities of Professional Rugby League Match Play

Delaney¹,

Duthie²,

Thornton³

et al. 2016

International Journal of Sports Physiology and Performance

113

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Rugby league involves frequent periods of high-intensity running including acceleration and deceleration efforts, often occurring at low speeds. Purpose: To quantify the energetic cost of running and acceleration efforts during rugby league competition to aid in prescription and monitoring of training. Methods: Global Positioning System (GPS) data were collected from 37 professional rugby league players across two seasons. Peak values for relative distance, average acceleration/deceleration and metabolic power (Pmet) were calculated for ten different moving average durations (1-10 min), for each position. A mixed-effects model was used to assess the effect of position for each duration, and individual comparisons were made using a magnitude-based inference network. Results: There were almost certainly large differences in relative distance and Pmet between the 10-min window and all moving averages <5 min in duration (ES = 1.21-1.88). Fullbacks, halves and hookers covered greater relative distances than outside backs, edge forwards and middle forwards for moving averages lasting between 2-10 min. Acceleration/deceleration demands were greatest in hookers and halves compared to fullbacks, middle forwards and outside backs. Pmet was greatest in hookers, halves and fullbacks compared to middle forwards and outside backs. Conclusions: Competition running intensities varied by both position and moving average duration. Hookers exhibited the greatest Pmet of all positions, due to high involvement in both attack and defence. Fullbacks also reached high Pmet, possibly due to a greater absolute volume of running. This study provides coaches with match data that can be used for the prescription and monitoring of specific training drills.

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“…Hoppe, Baumgart, and Freiwald (2016) examined the metabolic power of both adolescent and adult tennis players. The instantaneous metabolic power (MP) is the quantification of the amount of energy required per unit of time to reconstitute the ATP utilised during performance on the bases of oxidative process; it is expressed in equivalent O 2 units regardless of the actual oxygen consumptions because the latter could be greater, equal of smaller compared to the effective metabolic power (Prampero (di), Botter, & Osgnach, 2015). In the present study, this parameter has been monitored to support the assessment of the player load by analysing the time spent in each intensity threshold.…”

Section: Variablesmentioning

confidence: 99%

Movement analysis and metabolic profile of tennis match play: comparison between hard courts and clay courts

Ponzano

Gollin

2017

International Journal of Performance Analysis in Sport

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This study aimed to define the movement analysis and metabolic model in tennis on hard courts and clay courts. Twenty-four tennis players were equipped with a 15 Hz GPS and a Polar. H7 and played a match on each playing surface. The average duration of matches was 76 Å} 24 (C) and 69 Å} 17 min (H). The maximum heart rate (HRmax) was 185 Å} 14 (C) and 178 Å} 10 bpm (H), the average heart rate (HRav) was 144 Å} 14 (C) and 139 Å} 12 bpm (H). The average metabolic power (MPav) was 3.93 Å} .34 (C) and 3.70 Å} .34 W Å~ kg−1 (H) (ES = .72, C > H, +6%). The ANOVA and the post hoc showed significant differences regarding the considered parameters on both the surfaces. The t-test highlighted significant surface-related differences (ES = .88, C > H, +26%) concerning accelerations performed between 50 and 60% of the maximum value, decelerations between 40 and 50% of the maximum (ES = 1.28, H > C, +37%), metabolic power between 0 and 10 W Å~ kg−1 (ES =

show abstract

The energy cost of sprint running and the role of metabolic power in setting top performances

Cited by 98 publications

References 40 publications

A simple method for measuring power, force, velocity properties, and mechanical effectiveness in sprint running

A simple method for measuring power, force, velocity properties, and mechanical effectiveness in sprint running

Acceleration-Based Running Intensities of Professional Rugby League Match Play

Movement analysis and metabolic profile of tennis match play: comparison between hard courts and clay courts

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