On the Importance of “Front-Side Mechanics” in Athletics Sprinting

Haugen, Thomas; Danielsen, Jørgen; Alnes, Leif Olav; McGhie, David; Sandbakk, Øyvind; Ettema, Gertjan

doi:10.1123/ijspp.2016-0812

Cited by 29 publications

(52 citation statements)

References 27 publications

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“…Sprint running is a fundamental skill in many sport disciplines. An optimal sprint running technique is regulated by a complex interaction of numerous variables, including mass‐specific force application, spatiotemporal variables, body configuration, and lower limb segment velocities prior to and during ground contact . However, the human running pattern is also associated with bilateral asymmetry, most likely due to imbalances in the neuromuscular and skeletal system .…”

Section: Introductionmentioning

confidence: 99%

Kinematic stride cycle asymmetry is not associated with sprint performance and injury prevalence in athletic sprinters

Haugen

Danielsen

McGhie

et al. 2017

Scandinavian Med Sci Sports

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The aims of this study were to (a) quantify the magnitude of kinematic stride cycle asymmetry in high-level athletic sprinters, (b) explore the association between kinematic asymmetry and maximal sprint running performance, and (c) investigate possible associations between kinematic asymmetry and injury prevalence. Twenty-two competitive sprinters (age 23 ± 3 year, height 1.81 ± 0.06 m, body mass 75.5 ± 5.6 kg, personal best 100 m 10.86 ± 0.22 seconds) performed 2-3 flying sprints over 20 m. Kinematics were recorded in 3D using a motion tracking system with 21 cameras at a 250 Hz sampling rate, allowing assessment of six consecutive steps for each athlete. Information about injuries sustained 1 year prior to and after the experiment was continuously registered (type, location, severity/duration, and time of year occurrence). The results showed that ≥11 of the 22 participating athletes displayed large or very large asymmetry for at least 11 of 14 variables, and all athletes displayed large or very large asymmetry for at least three variables. No correlations between individual magnitudes of asymmetry and sprint performance were significant (trivial to moderate). No significant changes in asymmetry between best and worst trial were observed for any of the analyzed variables. In addition, injured and non-injured athletes did not differ in asymmetry, neither for the time period 1 year prior to nor after the test. In conclusion, kinematic asymmetries in the stride cycle were not associated with neither maximal sprint running performance nor the prevalence of injury among high-level athletic sprinters.

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Section: Introductionmentioning

confidence: 99%

Kinematic stride cycle asymmetry is not associated with sprint performance and injury prevalence in athletic sprinters

Haugen

Danielsen

McGhie

et al. 2017

Scandinavian Med Sci Sports

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show abstract

“…Employing a large number (n = 79) of sprinters across a broad range of performance levels (10.30-12.14 s), multiple regression equations which took into account difference in running speed, leg length and spatiotemporal variables to predict kinematics of maximal speed sprinting were successfully obtained, and leg kinematics of greater maximal running speed based on leg length and step characteristics were elucidated using the multiple regression equations. Although there were previous studies that examined the relationship between running speed and each of kinematic variables (Kunz and Kaufmann, 1981;Alexander, 1989;Ae et al, 1992;Bushnell and Hunter, 2007;Ito et al, 2008;Yada et al, 2011;Toyoshima and Sakurai, 2016;Haugen et al, 2018), this study is the first to demonstrate kinematic features for faster sprinting performance, taking into account the characteristics of individuals in terms of leg length and spatiotemporal variables. Moreover, as the adjusted R 2 for all predicted kinematic variables were greater than R 2 for each of simple linear regression analyses (Supplementary Table 1), it is evident that not only running speed, but also leg length and spatiotemporal variables (step frequency and swing/support ratio), relate to leg kinematics.…”

Section: Discussionmentioning

confidence: 91%

“…Leg length was obtained as sum of average thigh and shank lengths which were taken by the digitized data across the whole stride cycle in reference to a previous study (Toyoshima and Sakurai, 2016). In reference to variables used in previous studies (Kunz and Kaufmann, 1981;Alexander, 1989;Ae et al, 1992;Hunter et al, 2004;Bushnell and Hunter, 2007;Ito et al, 2008;Yada et al, 2011;Toyoshima and Sakurai, 2016;Haugen et al, 2018), the kinematic variables listed in Table 1 were extracted.…”

Section: Data Processingmentioning

confidence: 99%

“…Associations of leg kinematics and maximal speed sprinting performance have broadly been investigated (Kunz and Kaufmann, 1981;Alexander, 1989;Ae et al, 1992;Bushnell and Hunter, 2007;Ito et al, 2008;Yada et al, 2011;Toyoshima and Sakurai, 2016;Haugen et al, 2018). For joint kinematics, greater maximal running speed was associated with more extended knee joint angle at the mid-support (Yada et al, 2011), smaller knee joint angle at toe-off (Bushnell and Hunter, 2007;Yada et al, 2011), greater minimal knee joint angle during the swing phase (Ito et al, 2008), greater hip extension velocity during the support phase (Ae et al, 1992;Ito et al, 2008), and smaller knee extension velocity during the support phase (Ito et al, 2008).…”

mentioning

confidence: 99%

“…Knowledge of difference in magnitudes of changes in kinematic variables associated with changes in running speed, leg length, and spatiotemporal variables would be of great value to coaches when training a sprinter to improve maximal speed sprinting performance. Moreover, because each of previous studies investigated relationships between maximal speed sprinting performance and kinematic variables for small number of variables (Kunz and Kaufmann, 1981;Alexander, 1989;Ae et al, 1992;Bushnell and Hunter, 2007;Ito et al, 2008;Yada et al, 2011;Toyoshima and Sakurai, 2016;Haugen et al, 2018), the data as normative information which can be used by coaches and sprinters are limited. Adopting a large number of kinematic variables therefore would provide normative information for considering faster maximal sprinting performance based on individual-specific factors.…”

mentioning

confidence: 99%

See 2 more Smart Citations

Kinematics of Maximal Speed Sprinting With Different Running Speed, Leg Length, and Step Characteristics

Miyashiro

Nagahara

Yamamoto

et al. 2019

Front. Sports Act. Living

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This study aimed to provide multiple regression equations taking into account differences in running speed, leg length, and step characteristics to predict kinematics of maximal speed sprinting. Seventy-nine male sprinters performed a maximal effort 60-m sprint, during which they were videoed through the section from the 40-to 50-m mark. From the video images, leg kinematic variables were obtained and used as dependent variables for multiple linear regression equation with predictors of running speed, leg length, step frequency, and swing/support ratio. Multiple regression equations to predict leg kinematics of maximal speed sprinting were successfully obtained. For swing leg kinematics, a significant regression model was obtained to predict thigh angle at the contralateral foot strike, maximal knee flexion and thigh lift angular velocities, and maximal leg backward swing velocity (adjusted R 2 = 0.194-0.378, medium to large effect). For support leg kinematics, a significant regression model was obtained to predict knee flexion and extension angular displacements, maximal knee extension velocity, maximal leg backward swing angular velocity, and the other 13 kinematic variables (adjusted R 2 = 0.134-0.757, medium to large effect). Based on the results, at a given leg length, faster maximal speed sprinting will be accompanied with greater thigh angle at the contralateral foot strike, greater maximal leg backward swing velocity during the swing phase, and smaller knee extension range during the support phase. Longer-legged sprinters will accomplish the same running speed with a greater thigh angle at contralateral foot strike, greater knee flexion range, and smaller maximal leg backward swing velocity during the support phase. At a given running speed and leg length, higher step frequencies will be achieved with a greater thigh angle at contralateral foot strike and smaller knee flexion and extension ranges during the support phase. At a given running speed, leg length and step frequency, a greater swing/support ratio will be accompanied with a greater thigh angle at contralateral foot strike and smaller knee extension angular displacement and velocity during the support phase. The regression equations obtained in this study will be useful for sprinters when trying to improve their maximal speed sprinting motion.

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Force–velocity profiling of sprinting athletes: single-run vs. multiple-run methods

Helland¹,

Haugen²,

Rakovic

et al. 2018

Eur J Appl Physiol

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On the Importance of “Front-Side Mechanics” in Athletics Sprinting

Cited by 29 publications

References 27 publications

Kinematic stride cycle asymmetry is not associated with sprint performance and injury prevalence in athletic sprinters

Kinematic stride cycle asymmetry is not associated with sprint performance and injury prevalence in athletic sprinters

Kinematics of Maximal Speed Sprinting With Different Running Speed, Leg Length, and Step Characteristics

Force–velocity profiling of sprinting athletes: single-run vs. multiple-run methods

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