Bernard J, Beldame J, Van Driessche S, Brunel H, Poirier T, Guiffault P, Matsoukis J, Billuart F
Laboratoire d'analyse du mouvement, Institut de formation en masso-kinésithérapie « Saint-Michel », 68, rue du Commerce, 75015 Paris, France.
Clinique Mégival, 1328, avenue de la Maison-Blanche, 76550 Saint-Aubin-sur-Scie, France.
Orthop Traumatol Surg Res. 2017 Nov;103(7):999-1004. doi: 10.1016/j.otsr.2017.07.009. Epub 2017 Aug 5.
Minimally invasive total hip arthroplasty (THA) is presumed to provide functional and clinical benefits, whereas in fact the literature reveals that gait and posturographic parameters following THA do not recover values found in the general population. There is a significant disturbance of postural sway in THA patients, regardless of the surgical approach, although with some differences between approaches compared to controls: the anterior and anterolateral minimally invasive approaches seem to be more disruptive of postural parameters than the posterior approach. Electromyographic (EMG) study of the hip muscles involved in surgery [gluteus maximus (GMax), gluteus medius (GMed), tensor fasciae latae (TFL), and sartorius (S)] could shed light, the relevant literature involves discordant methodologies. We developed a methodology to assess EMG activity during maximal voluntary contraction (MVC) of the GMax, GMed, TFL and sartorius muscles as a reference for normalization. A prospective study aimed to assess whether hip joint positioning and the learning curve on an MVC test affect the EMG signal during a maximal voluntary contraction.
Hip positioning and the learning curve on an MVC test affect EMG signal during MVC of GMax, GMed, TFL and S.
Thirty young asymptomatic subjects participated in the study. Each performed 8 hip muscle MVCs in various joint positions recorded with surface EMG sensors. Each MVC was performed 3 times in 1 week, with the same schedule every day, controlling for activity levels in the preceding 24h. EMG activity during MVC was expressed as a ratio of EMG activity during unipedal stance. Non-parametric tests were applied.
Statistical analysis showed no difference according to hip position for abductors or flexors in assessing EMG signal during MVC over the 3 sessions. Hip abductors showed no difference between abduction in lateral decubitus with hip straight versus hip flexed: GMax (19.8±13.7 vs. 14.5±7.8, P=0.78), GMed (13.4±9.0 vs. 9.9±6.6, P=0.21) and TFL (69.5±61.7 vs. 65.9±51.3, P=0.50). Flexors showed no difference between hip flexion/abduction/lateral rotation performed in supine or sitting position: TFL (70.6±45.9 vs. 61.6±45.8, P=0.22) and S (101.1±67.9 vs. 72.6±44.6, P=0.21). The most effective tests to assess EMG signal during MVC were for the hip abductors: hip abduction performed in lateral decubitus (36.7% for GMax, 76.7% for GMed), and for hip flexors: hip flexion/abduction/lateral rotation performed in supine decubitus (50% for TFL, 76.7% for S).
The study hypothesis was not confirmed, since hip joint positioning and the learning curve on an MVC test did not affect EMG signal during MVC of GMax, GMed, TFL and S muscles. Therefore, a single session and one specific test is enough to assess MVC in hip abductors (abduction in lateral decubitus) and flexors (hip flexion/abduction/lateral rotation in supine position). This method could be applied to assess muscle function after THA, and particularly to compare different approaches.
III, case-matched study.
微创全髋关节置换术(THA)被认为能带来功能和临床益处,然而实际上文献显示,THA后的步态和姿势描记参数并未恢复到普通人群中的数值。THA患者存在明显的姿势摇摆紊乱,无论手术入路如何,尽管与对照组相比不同入路之间存在一些差异:前路和前外侧微创入路似乎比后路入路对姿势参数的干扰更大。对手术中涉及的髋部肌肉[臀大肌(GMax)、臀中肌(GMed)、阔筋膜张肌(TFL)和缝匠肌(S)]进行肌电图(EMG)研究可能会有所帮助,但相关文献的方法并不一致。我们开发了一种方法来评估GMax、GMed、TFL和缝匠肌最大自主收缩(MVC)期间的EMG活动,作为标准化的参考。一项前瞻性研究旨在评估髋关节位置和MVC测试中的学习曲线是否会在最大自主收缩期间影响EMG信号。
髋关节位置和MVC测试中的学习曲线会在GMax、GMed、TFL和S肌的MVC期间影响EMG信号。
30名年轻无症状受试者参与了该研究。每人在不同关节位置进行8次髋部肌肉MVC,并用表面EMG传感器记录。每个MVC在1周内进行3次,每天的时间表相同,控制前24小时的活动水平。MVC期间的EMG活动表示为单腿站立期间EMG活动的比率。应用非参数检验。
统计分析显示,在3次测试中,评估MVC期间的EMG信号时,外展肌或屈肌根据髋关节位置无差异。髋关节外展肌在侧卧位髋关节伸直与屈曲时的外展之间无差异:GMax(19.8±13.7对14.5±7.8,P = 0.78)、GMed(13.4±9.0对9.9±6.6,P = 0.21)和TFL(69.5±61.7对65.9±51.3,P = 0.50)。屈肌在仰卧位或坐位进行髋关节屈曲/外展/外旋时无差异:TFL(70.6±45.9对61.6±45.8,P = 0.22)和S(101.1±67.9对72.6±44.6,P = 0.21)。评估MVC期间EMG信号最有效的测试是针对髋关节外展肌:侧卧位髋关节外展(GMax为36.7%,GMed为76.7%),以及针对髋关节屈肌:仰卧位髋关节屈曲/外展/外旋(TFL为50%,S为76.7%)。
研究假设未得到证实,因为髋关节位置和MVC测试中的学习曲线在GMax、GMed、TFL和S肌的MVC期间并未影响EMG信号。因此,单次测试和一种特定测试足以评估髋关节外展肌(侧卧位外展)和屈肌(仰卧位髋关节屈曲/外展/外旋)的MVC。该方法可用于评估THA后的肌肉功能,特别是用于比较不同入路。
III,病例对照研究。
