Túlio Bernardo Macedo Alfano Moura, Juliane Cristine Leme, Fábio Yuzo Nakamura, Jefferson Rosa Cardoso, Felipe Arruda Moura
{"title":"Determinant biomechanical variables for each sprint phase performance in track and field: A systematic review","authors":"Túlio Bernardo Macedo Alfano Moura, Juliane Cristine Leme, Fábio Yuzo Nakamura, Jefferson Rosa Cardoso, Felipe Arruda Moura","doi":"10.1177/17479541231200526","DOIUrl":null,"url":null,"abstract":"Sprint studies present several variables and methodologies for biomechanical analysis in different phases of running. The variability in the analysis of the sample and distance covered may impede the application of the results in track and field athletes. The objective of this systematic review was to characterize the determinant biomechanical variables analyzed in the literature in each sprint phase. Four electronic databases were used (MEDLINE, Web of Science, SportDiscus, and Scopus). Only biomechanical studies with track and field athletes were selected. After the identification, screening, and eligibility process, 109 studies were included for qualitative synthesis and analyzed by the risk of bias assessment. The studies were classified in different sprint phases, according to the sprint task described by the authors (sprint start = 27, acceleration = 32, constant speed = 8, deceleration = 4, and not specified = 38). Factors such as the center of mass position, contact time, force applied on the rear block, and athletes’ ability to generate high amounts of force in the shortest possible time influence the sprint start performance. The acceleration phase is characterized by step frequency and step length transition, propulsive force, and minimization of braking force. Consequently, directing the resulting force as vertically as possible in the braking phase and as horizontally as possible in the anterior direction during the propulsive phase is important during the constant speed phase. In the deceleration phase, the decrease in step frequency and the increase in contact time may influence speed maintenance and, consequently, the result.","PeriodicalId":47767,"journal":{"name":"International Journal of Sports Science & Coaching","volume":"6 22","pages":"0"},"PeriodicalIF":1.5000,"publicationDate":"2023-11-07","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"International Journal of Sports Science & Coaching","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.1177/17479541231200526","RegionNum":4,"RegionCategory":"教育学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q3","JCRName":"HOSPITALITY, LEISURE, SPORT & TOURISM","Score":null,"Total":0}
引用次数: 0
Abstract
Sprint studies present several variables and methodologies for biomechanical analysis in different phases of running. The variability in the analysis of the sample and distance covered may impede the application of the results in track and field athletes. The objective of this systematic review was to characterize the determinant biomechanical variables analyzed in the literature in each sprint phase. Four electronic databases were used (MEDLINE, Web of Science, SportDiscus, and Scopus). Only biomechanical studies with track and field athletes were selected. After the identification, screening, and eligibility process, 109 studies were included for qualitative synthesis and analyzed by the risk of bias assessment. The studies were classified in different sprint phases, according to the sprint task described by the authors (sprint start = 27, acceleration = 32, constant speed = 8, deceleration = 4, and not specified = 38). Factors such as the center of mass position, contact time, force applied on the rear block, and athletes’ ability to generate high amounts of force in the shortest possible time influence the sprint start performance. The acceleration phase is characterized by step frequency and step length transition, propulsive force, and minimization of braking force. Consequently, directing the resulting force as vertically as possible in the braking phase and as horizontally as possible in the anterior direction during the propulsive phase is important during the constant speed phase. In the deceleration phase, the decrease in step frequency and the increase in contact time may influence speed maintenance and, consequently, the result.
短跑研究为跑步不同阶段的生物力学分析提供了几个变量和方法。样本分析和覆盖距离的可变性可能会阻碍结果在田径运动员中的应用。本系统综述的目的是表征每个冲刺阶段文献中分析的决定性生物力学变量。使用了四个电子数据库(MEDLINE, Web of Science, SportDiscus和Scopus)。只选择了田径运动员的生物力学研究。经过鉴定、筛选和入选过程,纳入109项研究进行定性综合,并进行偏倚风险评估分析。根据作者描述的冲刺任务(冲刺开始= 27,加速= 32,匀速= 8,减速= 4,未指定= 38),将研究分为不同的冲刺阶段。诸如重心位置、接触时间、施加在后块上的力以及运动员在尽可能短的时间内产生大量力的能力等因素都会影响短跑起跑的表现。加速阶段的特点是步进频率和步长过渡、推进力和制动力的最小化。因此,在恒速阶段,在制动阶段尽可能垂直地引导所产生的力,在推进阶段尽可能在前方向水平地引导所产生的力是很重要的。在减速阶段,步进频率的降低和接触时间的增加可能会影响速度保持,从而影响结果。
期刊介绍:
The International Journal of Sports Science & Coaching is a peer-reviewed, international, academic/professional journal, which aims to bridge the gap between coaching and sports science. The journal will integrate theory and practice in sports science, promote critical reflection of coaching practice, and evaluate commonly accepted beliefs about coaching effectiveness and performance enhancement. Open learning systems will be promoted in which: (a) sports science is made accessible to coaches, translating knowledge into working practice; and (b) the challenges faced by coaches are communicated to sports scientists. The vision of the journal is to support the development of a community in which: (i) sports scientists and coaches respect and learn from each other as they assist athletes to acquire skills by training safely and effectively, thereby enhancing their performance, maximizing their enjoyment of the sporting experience and facilitating character development; and (ii) scientific research is embraced in the quest to uncover, understand and develop the processes involved in sports coaching and elite performance.