Briand Jérémy, Deguire Simon, Gaudet Sylvain, Bieuzen François
Institut National du Sport du Québec, Montréal, QC, Canada.
Front Sports Act Living. 2022 Jul 14;4:896828. doi: 10.3389/fspor.2022.896828. eCollection 2022.
Injuries limit the athletes' ability to participate fully in their training and competitive process. They are detrimental to performance, affecting the athletes psychologically while limiting physiological adaptations and long-term development. This study aims to present a framework for developing random forest classifier models, forecasting injuries in the upcoming 1 to 7 days, to assist the performance support staff in reducing injuries and maximizing performance within the Canadian National Female Short-Track Speed Skating Program. Forty different variables monitored daily over two seasons (2018-2019 and 2019-2020) were used to develop two sets of forecasting models. One includes only training load variables (TL), and a second (ALL) combines a wide array of monitored variables (neuromuscular function, heart rate variability, training load, psychological wellbeing, past injury type, and location). The sensitivity (ALL: 0.35 ± 0.19, TL: 0.23 ± 0.03), specificity (ALL: 0.81 ± 0.05, TL: 0.74 ± 0.03) and Matthews Correlation Coefficients (MCC) (ALL: 0.13 ± 0.05, TL: -0.02 ± 0.02) were computed. Paired -test on the MCC revealed statistically significant ( < 0.01) and large positive effects (Cohen d > 1) for the ALL forecasting models' MCC over every forecasting window (1 to 7 days). These models were highly determined by the athletes' training completion, lower limb and trunk/lumbar injury history, as well as sFatigue, a training load marker. The TL forecasting models' MCC suggests they do not bring any added value to forecast injuries. Combining a wide array of monitored variables and quantifying the injury etiology conceptual components significantly improve the injury forecasting performance of random forest models. The ALL forecasting models' performances are promising, especially on one time windows of one or two days, with sensitivities and specificities being respectively above 0.5 and 0.7. They could add value to the decision-making process for the support staff in order to assist the Canadian National Female Team Short-Track Speed Skating program in reducing the number of incomplete training days, which could potentially increase performance. On longer forecasting time windows, ALL forecasting models' sensitivity and MCC decrease gradually. Further work is needed to determine if such models could be useful for forecasting injuries over three days or longer.
伤病限制了运动员充分参与训练和比赛过程的能力。它们对运动表现有害,在限制生理适应和长期发展的同时,还会对运动员产生心理影响。本研究旨在提出一个开发随机森林分类器模型的框架,预测未来1至7天内的伤病情况,以协助加拿大国家女子短道速滑项目的表现支持人员减少伤病并最大化运动表现。在两个赛季(2018 - 2019年和2019 - 2020年)中每天监测的40个不同变量被用于开发两组预测模型。一组仅包括训练负荷变量(TL),另一组(ALL)则结合了一系列监测变量(神经肌肉功能、心率变异性、训练负荷、心理健康、既往伤病类型和部位)。计算了敏感度(ALL:0.35±0.19,TL:0.23±0.03)、特异度(ALL:0.81±0.05,TL:0.74±0.03)和马修斯相关系数(MCC)(ALL:0.13±0.05,TL: - 0.02±0.02)。对MCC进行配对t检验显示,在每个预测窗口(1至7天)内,ALL预测模型的MCC具有统计学显著性(p < 0.01)和较大的正向效应(科恩d > 1)。这些模型高度取决于运动员的训练完成情况、下肢和躯干/腰部伤病史以及训练负荷指标sFatigue。TL预测模型的MCC表明它们在预测伤病方面没有带来任何附加价值。结合一系列监测变量并量化伤病病因概念成分可显著提高随机森林模型的伤病预测性能。ALL预测模型的表现很有前景,尤其是在1天或2天的时间窗口内,敏感度和特异度分别高于0.5和0.7。它们可为支持人员的决策过程增加价值,以协助加拿大国家女子短道速滑队减少不完整训练天数,这可能会提高运动表现。在更长的预测时间窗口内,ALL预测模型的敏感度和MCC会逐渐降低。需要进一步开展工作来确定此类模型是否对预测三天或更长时间的伤病有用。
