脑电图
体感诱发电位
体感系统
物理医学与康复
神经科学
心理学
运动学
认知心理学
听力学
医学
物理
经典力学
作者
Jinyan Zhang,Weiao Zou,Binbin Gao,Jinglong Wu,Zhilin Zhang,Jian Zhang,Luyao Wang,Tianyi Yan
摘要
ABSTRACT Aims Motor training enhances somatosensory temporal discrimination threshold (STDT), but the distinct neural mechanisms underlying actual execution versus motor imagery remain unclear. This study aimed to compare the effects of ball‐rotation training (BRT; actual execution) and visual‐guided imagery (VGI; motor imagery) on STDT, kinematic performance, and neurophysiological plasticity in healthy adults. Methods Forty‐eight right‐handed participants were randomized into four groups: BRT (actual execution), VGI (motor imagery without movement), tactile control (simple gripping), and no‐intervention control. Over seven days, participants underwent pre‐/post‐training assessments including kinematic analysis, STDT measurement, power spectral analysis and somatosensory‐evoked potentials (SEPs). Results BRT significantly enhanced motor performance (83% score increase vs. 21% in controls, p < 0.001) and movement speed (37% cycle time reduction vs. 12%–16% in others, p < 0.001), with partial transfer to the untrained hand. Both interventions reduced STDT but at distinct locations: BRT selectively improved index finger discrimination (64.02 ms → 43.75 ms, p = 0.007), while VGI enhanced palm sensitivity (73.43 ms → 61.13 ms, p = 0.003). Neurophysiologically, SEPs revealed increased spatial inhibition ratio (SIR) plasticity in both BRT and VGI ( p < 0.001), correlating with STDT gains. EEG demonstrated BRT‐induced gamma‐band power increases in parietal regions and theta‐band elevations in prefrontal cortex, whereas VGI modulated delta‐band activity in ipsilateral parietal cortex. Conclusion Actual execution (BRT) and motor imagery (VGI) enhance STDT through distinct neuroplastic mechanisms: BRT optimizes sensorimotor integration via parietal gamma/prefrontal theta oscillations, while VGI relies on ipsilateral parietal delta modulation. These findings underscore the role of cortical reorganization in motor learning and support tailored rehabilitation strategies for neurological disorders.
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