University of Florida, Gainesville, USA.
Colorado State University, Fort Collins, USA.
Exp Brain Res. 2024 May;242(5):1115-1126. doi: 10.1007/s00221-024-06798-8. Epub 2024 Mar 14.
The use of functional near-infrared spectroscopy (fNIRS) for brain imaging during human movement continues to increase. This technology measures brain activity non-invasively using near-infrared light, is highly portable, and robust to motion artifact. However, the spatial resolution of fNIRS is lower than that of other imaging modalities. It is unclear whether fNIRS has sufficient spatial resolution to differentiate nearby areas of the cortex, such as the leg areas of the motor cortex. Therefore, the purpose of this study was to determine fNIRS' ability to discern laterality of lower body contractions. Activity in the primary motor cortex was recorded in forty participants (mean = 23.4 years, SD = 4.5, female = 23, male = 17) while performing unilateral lower body contractions. Contractions were performed at 30% of maximal force against a handheld dynamometer. These contractions included knee extension, knee flexion, dorsiflexion, and plantar flexion of the left and right legs. fNIRS signals were recorded and stored for offline processing and analysis. Channels of fNIRS data were grouped into regions of interest, with five tolerance conditions ranging from strict to lenient. Four of five tolerance conditions resulted in significant differences in cortical activation between hemispheres. During right leg contractions, the left hemisphere was more active than the right hemisphere. Similarly, during left leg contractions, the right hemisphere was more active than the left hemisphere. These results suggest that fNIRS has sufficient spatial resolution to distinguish laterality of lower body contractions. This makes fNIRS an attractive technology in research and clinical applications in which laterality of brain activity is required during lower body activity.
功能性近红外光谱(fNIRS)在人类运动期间进行脑成像的应用不断增加。该技术使用近红外光非侵入性地测量脑活动,具有高度便携性和对运动伪影的稳健性。然而,fNIRS 的空间分辨率低于其他成像方式。目前尚不清楚 fNIRS 是否具有足够的空间分辨率来区分皮质的附近区域,例如运动皮质的腿部区域。因此,本研究的目的是确定 fNIRS 区分下半身收缩的左右侧的能力。在四十名参与者(平均年龄为 23.4 岁,标准差为 4.5,女性为 23 名,男性为 17 名)进行单侧下半身收缩时,记录初级运动皮质的活动。收缩是在手持测力计上以 30%的最大力进行的。这些收缩包括左腿和右腿的膝关节伸展、膝关节弯曲、背屈和跖屈。记录并存储 fNIRS 信号以进行离线处理和分析。fNIRS 数据的通道被分为感兴趣区域,有五个从严格到宽松的容限条件。在四个容限条件中,有三个条件导致了半球之间皮质激活的显著差异。在右腿收缩期间,左半球比右半球更活跃。同样,在左腿收缩期间,右半球比左半球更活跃。这些结果表明,fNIRS 具有足够的空间分辨率来区分下半身收缩的左右侧。这使得 fNIRS 在需要在下半身活动期间测量大脑活动的左右侧的研究和临床应用中具有吸引力。
