Musculoskeletal Rehabilitation Research Group, Department of Rehabilitation Sciences and Physiotherapy, Faculty of Kinesiology and Rehabilitation Sciences, KU Leuven, BELGIUM.
Department of Orthopedic Surgery, AZ Herentals Hospital, Herentals, BELGIUM.
Med Sci Sports Exerc. 2020 Feb;52(2):345-353. doi: 10.1249/MSS.0000000000002143.
Fatigue has a negative impact on lower extremity neuromuscular and biomechanical control. Because anterior cruciate ligament reconstruction (ACLR) athletes show already neuromuscular/biomechanical deficits in an unfatigued state, the negative impact of fatigue may magnify these deficits or help expose other deficits. So far, this has only scarcely been assessed warranting further research.
Twenty-one athletes who had an ACLR and 21 uninjured controls performed five unilateral landing tasks before and after a match simulation protocol, whereas muscle activation (vastus medialis, vastus lateralis, hamstrings medialis, hamstrings lateralis, gastrocnemius medialis, gastrocnemius lateralis, gluteus medius) and landing kinematics and kinetics of the hip, knee, and ankle joint were recorded. A two-way ANOVA with a mixed-model design (main effects for group and fatigue) was used to compare landing kinematics, kinetics, and muscle activation between groups, and prefatigue and postfatigue. To avoid unjustified reduction of the data to discrete values, we used one-dimensional Statistical Parametric Mapping.
Only two interaction effects were found: an increased postfatigue knee abduction moment and an increased postfatigue thorax flexion angle was found in the ACL injured legs but not in the uninjured legs of the ACL group or in the control group, during the lateral hop and the vertical hop with 90° medial rotation, respectively.
This study showed that overall ACLR athletes and uninjured athletes have similar biomechanical and neuromuscular responses to fatigue. For two biomechanical parameters, however, we did find an interaction effect, suggesting that landing deficits in ACLR athletes may become clearer in certain tasks when fatigued.
疲劳会对下肢的神经肌肉和生物力学控制产生负面影响。由于前交叉韧带重建(ACLR)运动员在未疲劳状态下已经表现出神经肌肉/生物力学缺陷,因此疲劳的负面影响可能会放大这些缺陷或有助于暴露其他缺陷。到目前为止,这只是很少被评估的,需要进一步研究。
21 名 ACLR 运动员和 21 名未受伤的对照组运动员在进行模拟比赛前和模拟比赛后分别进行了 5 次单侧着陆任务,同时记录了髋关节、膝关节和踝关节的肌肉激活(股直肌、股外侧肌、股内侧肌、股外侧肌、腓肠肌内侧、腓肠肌外侧、臀中肌)和着陆运动学及动力学。采用混合模型设计的双因素方差分析(组间和疲劳的主效应)来比较组间、预疲劳和后疲劳状态下的着陆运动学、动力学和肌肉激活。为避免对数据进行不合理的离散值处理,我们使用了一维统计参数映射。
仅发现了两个交互作用效应:在 ACL 受伤腿的侧向跳跃和 90°内侧旋转的垂直跳跃中,分别发现了后疲劳时膝关节外展力矩增加和后疲劳时胸腰椎前屈角度增加,但在 ACL 组的未受伤腿和对照组中没有发现。
本研究表明,ACL 重建运动员和未受伤运动员在对疲劳的生物力学和神经肌肉反应总体上相似。然而,对于两个生物力学参数,我们确实发现了一个交互作用效应,这表明在某些任务中,当 ACL 重建运动员疲劳时,他们的着陆缺陷可能会更加明显。
