重力变化下胸腰椎曲度及脊柱肌肉活动的适应性
Adaptation of thoracic and lumbar curvature and spinal muscle activity under changing gravity.
作者信息
Meinke Anita, Baez Alessandro Longhi, Wiesmann Niklas, Ullrich Oliver, Green David A, Egli Marcel, Swanenburg Jaap
机构信息
Faculty of Medicine, Institute of Aerospace Medicine, University of Zurich, Zurich, Switzerland.
Faculty of Medicine, Institute of Anatomy, University of Zurich, Zurich, Switzerland.
出版信息
Front Physiol. 2025 May 20;16:1549249. doi: 10.3389/fphys.2025.1549249. eCollection 2025.
INTRODUCTION
The effect of micro-gravity on the lumbar and in particular thoracic regions is poorly understood. The aim of this study was to evaluate spinal curvature across the lumbar and thoracic region, and extensor muscle activity during acute micro-gravity and hyper-gravity induced by parabolic flight. In addition, the association between our proxy measure of spinal curvature, and extensor muscle activity in micro-gravity was investigated.
METHODS
During two ESA parabolic flight campaigns, 18 participants (8 female; 33 11 years) were measured under earth-gravity, micro-gravity and hyper-gravity conditions. Spinal curvature was assessed using "spinal curvature backpacks" equipped with 15 laser distance sensors to measure the distance between the backpack and the subject's back. Change in the area enclosed between the back and the backpack was used to measure change in spinal curvature. Muscle activity of the erector spinae (in 4 locations) and multifidus muscles (1 location) was assessed using surface electromyography transmitters. In addition, the spearmen correlation between muscle activity and spinal curvature in micro-gravity was investigated.
RESULTS
Spinal flattening was observed during micro-gravity exposure, with changes most pronounced in the upper lumbar and lower thoracic spine. Mean-normalized area between the back and backpack decreased significantly in micro-gravity compared to earth-gravity (p = 0.001), but not during hyper-gravity (p = 1.00). The erector spinae responded heterogeneously to different gravity conditions across different assessment sites. Multifidus activity at L5 and erector spinae activity at L4 significantly decreased in micro-gravity compared to earth-gravity and hyper-gravity (p's 0.01) and correlated with spinal flattening ( = 0.69, p = 0.004; = 0.67, p = 0.030).
DISCUSSION/CONCLUSION: Parabolic flight-induced gravity changes caused upper lumbar and lower thoracic spine flattening in micro-g, while spinal curvature remained unchanged in hyper-g. In micro-g, Multifidus (L5) and Erector Spinae (L4) activity decreased, while in hyper-g, increased ES activity was observed at the upper middle transmitter. The maintained curvature and targeted muscle activation in hyper-g demonstrate protective mechanisms against increased axial loading, crucial for posture and injury prevention in both terrestrial and space environments. The spinal and muscular changes in micro-g indicate the need for targeted countermeasures during spaceflight, warranting comprehensive assessment in future research.
ETHICS
French "EST-III" (Nr-ID-RCB: 2022-A01696-37).
引言
微重力对腰椎尤其是胸椎区域的影响尚不清楚。本研究的目的是评估腰椎和胸椎区域的脊柱曲率,以及抛物线飞行诱导的急性微重力和超重状态下伸肌的活动。此外,还研究了我们的脊柱曲率替代指标与微重力下伸肌活动之间的关联。
方法
在欧洲航天局的两次抛物线飞行任务中,对18名参与者(8名女性;年龄33±11岁)在地球重力、微重力和超重条件下进行了测量。使用配备15个激光距离传感器的“脊柱曲率背包”来评估脊柱曲率,以测量背包与受试者背部之间的距离。背部与背包之间围成区域的变化用于测量脊柱曲率的变化。使用表面肌电图发射器评估竖脊肌(4个部位)和多裂肌(1个部位)的肌肉活动。此外,还研究了微重力下肌肉活动与脊柱曲率之间的斯皮尔曼相关性。
结果
在微重力暴露期间观察到脊柱变平,在上腰椎和下胸椎区域变化最为明显。与地球重力相比,微重力下背部与背包之间的平均归一化面积显著减小(p = 0.001),但在超重状态下没有变化(p = 1.00)。竖脊肌在不同评估部位对不同重力条件的反应存在异质性。与地球重力和超重状态相比,微重力下L5水平的多裂肌活动以及L4水平的竖脊肌活动显著降低(p值均≤0.01),且与脊柱变平相关(r = 0.69,p = 0.004;r = 0.67,p = 0.030)。
讨论/结论:抛物线飞行诱导的重力变化导致微重力状态下上腰椎和下胸椎变平,而超重状态下脊柱曲率保持不变。在微重力状态下,多裂肌(L5)和竖脊肌(L4)活动降低,而在超重状态下,在上中发射器处观察到竖脊肌活动增加。超重状态下维持的脊柱曲率和有针对性的肌肉激活表明存在针对轴向负荷增加的保护机制,这对于陆地和太空环境中的姿势和损伤预防至关重要。微重力状态下的脊柱和肌肉变化表明在太空飞行期间需要有针对性的应对措施,值得在未来研究中进行全面评估。
伦理
法国“EST-III”(编号:RCB:2022-A01696-37)
Zotero 插件