Landing-Takeoff Asymmetries Applied to Running Mechanics: A New Perspective for Performance

Landing-Takeoff Asymmetries Applied to Running Mechanics: A New Perspective for Performance

Background:Elastic bouncing is a physio-mechanical model that can elucidate running behavior in different situations, including landing and takeoff patterns and the characteristics of the muscle-tendon units during stretch and recoil in running. An increase in running speed improves the body’s elast...

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Main Authors: Rodrigo Gomes da Rosa, Henrique Bianchi Oliveira, Natalia Andrea Gomeñuka, Marcos Paulo Bienert Masiero, Edson Soares da Silva, Ana Paula Janner Zanardi, Alberito Rodrigo de Carvalho, Pedro Schons, Leonardo Alexandre Peyré-Tartaruga
Format: Article
Language:English
Published: Frontiers Media S.A. 2019-04-01
Series:Frontiers in Physiology
Subjects:
kinetic
forces
spring-mass system
muscle function
biomechanics
physical endurance
Online Access:https://www.frontiersin.org/article/10.3389/fphys.2019.00415/full
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spelling doaj-beb84876a0ee42d088f7822c4f083ac32020-11-25T00:29:52ZengFrontiers Media S.A.Frontiers in Physiology1664-042X2019-04-011010.3389/fphys.2019.00415436203Landing-Takeoff Asymmetries Applied to Running Mechanics: A New Perspective for PerformanceRodrigo Gomes da Rosa0Henrique Bianchi Oliveira1Natalia Andrea Gomeñuka2Marcos Paulo Bienert Masiero3Edson Soares da Silva4Ana Paula Janner Zanardi5Alberito Rodrigo de Carvalho6Pedro Schons7Leonardo Alexandre Peyré-Tartaruga8Laboratório de Pesquisa do Exercício, Universidade Federal do Rio Grande do Sul, Porto Alegre, BrazilLaboratório de Pesquisa do Exercício, Universidade Federal do Rio Grande do Sul, Porto Alegre, BrazilDepartamento de Investigación de la Facultad de Ciencias de la Salud, Universidad Católica de las Misiones (UCAMI), Posadas, ArgentinaLaboratório de Pesquisa do Exercício, Universidade Federal do Rio Grande do Sul, Porto Alegre, BrazilLaboratório de Pesquisa do Exercício, Universidade Federal do Rio Grande do Sul, Porto Alegre, BrazilLaboratório de Pesquisa do Exercício, Universidade Federal do Rio Grande do Sul, Porto Alegre, BrazilPhysical Therapy College, Universidade Estadual do Oeste do Paraná (UNIOESTE), Cascavel, BrazilLaboratório de Pesquisa do Exercício, Universidade Federal do Rio Grande do Sul, Porto Alegre, BrazilLaboratório de Pesquisa do Exercício, Universidade Federal do Rio Grande do Sul, Porto Alegre, BrazilBackground:Elastic bouncing is a physio-mechanical model that can elucidate running behavior in different situations, including landing and takeoff patterns and the characteristics of the muscle-tendon units during stretch and recoil in running. An increase in running speed improves the body’s elastic mechanisms. Although some measures of elastic bouncing are usually carried out, a general description of the elastic mechanism has not been explored in running performance. This study aimed to compare elastic bouncing parameters between the higher- and lower-performing athletes in a 3000 m test.Methods:Thirty-eight endurance runners (men) were divided into two groups based on 3000 m performance: the high-performance group (Phigh; n = 19; age: 29 ± 5 years; mass: 72.9 ± 10 kg; stature: 177 ± 8 cm; 3000time: 656 ± 32 s) and the low-performance group (Plow; n = 19; age: 32 ± 6 years; mass: 73.9 ± 7 kg; stature: 175 ± 5 cm; 3000time: 751 ± 29 s). They performed three tests on different days: (i) 3000 m on a track; (ii) incremental running test; and (iii) a running biomechanical test on a treadmill at 13 different speeds from 8 to 20 km h−1. Performance was evaluated using the race time of the 3000 m test. The biomechanics variables included effective contact time (tce), aerial time (tae), positive work time (tpush), negative work time (tbreak), step frequency (fstep), and elastic system frequency (fsist), vertical displacement (Sv) in tce and tae (Sce and Sae), vertical force, and vertical stiffness were evaluated in a biomechanical submaximal test on treadmill.Results:The tae, fsist, vertical force and stiffness were higher (p < 0.05) and tce and fstep were lower (p < 0.05) in Phigh, with no differences between groups in tpush and tbreak.Conclusion:The elastic bouncing was optimized in runners of the best performance level, demonstrating a better use of elastic components.https://www.frontiersin.org/article/10.3389/fphys.2019.00415/fullkineticforcesspring-mass systemmuscle functionbiomechanicsphysical endurance
collection DOAJ
language English
format Article
sources DOAJ
author Rodrigo Gomes da Rosa
Henrique Bianchi Oliveira
Natalia Andrea Gomeñuka
Marcos Paulo Bienert Masiero
Edson Soares da Silva
Ana Paula Janner Zanardi
Alberito Rodrigo de Carvalho
Pedro Schons
Leonardo Alexandre Peyré-Tartaruga
spellingShingle Rodrigo Gomes da Rosa
Henrique Bianchi Oliveira
Natalia Andrea Gomeñuka
Marcos Paulo Bienert Masiero
Edson Soares da Silva
Ana Paula Janner Zanardi
Alberito Rodrigo de Carvalho
Pedro Schons
Leonardo Alexandre Peyré-Tartaruga
Landing-Takeoff Asymmetries Applied to Running Mechanics: A New Perspective for Performance
Frontiers in Physiology
kinetic
forces
spring-mass system
muscle function
biomechanics
physical endurance
author_facet Rodrigo Gomes da Rosa
Henrique Bianchi Oliveira
Natalia Andrea Gomeñuka
Marcos Paulo Bienert Masiero
Edson Soares da Silva
Ana Paula Janner Zanardi
Alberito Rodrigo de Carvalho
Pedro Schons
Leonardo Alexandre Peyré-Tartaruga
author_sort Rodrigo Gomes da Rosa
title Landing-Takeoff Asymmetries Applied to Running Mechanics: A New Perspective for Performance
title_short Landing-Takeoff Asymmetries Applied to Running Mechanics: A New Perspective for Performance
title_full Landing-Takeoff Asymmetries Applied to Running Mechanics: A New Perspective for Performance
title_fullStr Landing-Takeoff Asymmetries Applied to Running Mechanics: A New Perspective for Performance
title_full_unstemmed Landing-Takeoff Asymmetries Applied to Running Mechanics: A New Perspective for Performance
title_sort landing-takeoff asymmetries applied to running mechanics: a new perspective for performance
publisher Frontiers Media S.A.
series Frontiers in Physiology
issn 1664-042X
publishDate 2019-04-01
description Background:Elastic bouncing is a physio-mechanical model that can elucidate running behavior in different situations, including landing and takeoff patterns and the characteristics of the muscle-tendon units during stretch and recoil in running. An increase in running speed improves the body’s elastic mechanisms. Although some measures of elastic bouncing are usually carried out, a general description of the elastic mechanism has not been explored in running performance. This study aimed to compare elastic bouncing parameters between the higher- and lower-performing athletes in a 3000 m test.Methods:Thirty-eight endurance runners (men) were divided into two groups based on 3000 m performance: the high-performance group (Phigh; n = 19; age: 29 ± 5 years; mass: 72.9 ± 10 kg; stature: 177 ± 8 cm; 3000time: 656 ± 32 s) and the low-performance group (Plow; n = 19; age: 32 ± 6 years; mass: 73.9 ± 7 kg; stature: 175 ± 5 cm; 3000time: 751 ± 29 s). They performed three tests on different days: (i) 3000 m on a track; (ii) incremental running test; and (iii) a running biomechanical test on a treadmill at 13 different speeds from 8 to 20 km h−1. Performance was evaluated using the race time of the 3000 m test. The biomechanics variables included effective contact time (tce), aerial time (tae), positive work time (tpush), negative work time (tbreak), step frequency (fstep), and elastic system frequency (fsist), vertical displacement (Sv) in tce and tae (Sce and Sae), vertical force, and vertical stiffness were evaluated in a biomechanical submaximal test on treadmill.Results:The tae, fsist, vertical force and stiffness were higher (p < 0.05) and tce and fstep were lower (p < 0.05) in Phigh, with no differences between groups in tpush and tbreak.Conclusion:The elastic bouncing was optimized in runners of the best performance level, demonstrating a better use of elastic components.
topic kinetic
forces
spring-mass system
muscle function
biomechanics
physical endurance
url https://www.frontiersin.org/article/10.3389/fphys.2019.00415/full
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