Locomotion Laboratory, Department of Integrative Physiology, University of Colorado, Boulder, CO, 80309.
Am J Phys Anthropol. 2014 Jan;153(1):124-31. doi: 10.1002/ajpa.22419. Epub 2013 Nov 12.
It has been suggested that the uniquely large gluteus maximus (GMAX) muscles were an important adaptation during hominin evolution based on numerous anatomical differences between humans and extant apes. GMAX electromyographic (EMG) signals have been quantified for numerous individual movements, but not across the range of locomotor gaits and speeds for the same subjects. Thus, comparing relative EMG amplitudes between these activities has not been possible. We assessed the EMG activity of the gluteal muscles during walking, running, sprinting, and climbing. To gain further insight into the function of the gluteal muscles during locomotion, we measured muscle activity during walking and running with external devices that increased or decreased the need to control either forward or backward trunk pitch. We hypothesized that 1) GMAX EMG activity would be greatest during sprinting and climbing and 2) GMAX EMG activity would be modulated in response to altered forward trunk pitch demands during running. We found that GMAX activity in running was greater than walking and similar to climbing. However, the activity during sprinting was much greater than during running. Further, only the inferior portion of the GMAX had a significant change with altered trunk pitch demands, suggesting that the hip extensors have a limited contribution to the control of trunk pitch movements during running. Overall, our data suggest that the large size of the GMAX reflects its multifaceted role during rapid and powerful movements rather than as a specific adaptation for a single submaximal task such as endurance running.
有人认为,独特的臀大肌(GMAX)在人类进化过程中是一个重要的适应,这基于人类和现生猿类之间众多的解剖学差异。GMAX 肌电图(EMG)信号已经被量化用于许多单独的运动,但不是在相同的受试者的所有步态和速度范围内。因此,比较这些活动之间的相对 EMG 幅度是不可能的。我们评估了在行走、跑步、短跑和攀爬时臀肌的 EMG 活动。为了更深入地了解臀肌在运动中的功能,我们在行走和跑步时使用外部设备测量了肌肉活动,这些设备增加或减少了对控制躯干前倾或后倾的需求。我们假设:1)GMAX EMG 活动在短跑和攀爬时最大;2)GMAX EMG 活动会根据跑步时改变的躯干前倾需求进行调节。我们发现,跑步时的 GMAX 活动大于行走时,与攀爬时相似。然而,短跑时的活动要大得多。此外,只有 GMAX 的下部在改变躯干俯仰需求时有明显的变化,这表明在跑步时,髋关节伸肌对控制躯干俯仰运动的贡献有限。总的来说,我们的数据表明,GMAX 的大尺寸反映了它在快速和有力的运动中的多方面作用,而不是作为单一亚最大任务(如耐力跑步)的特定适应。
