Neuromuscular mechanisms of motor adaptation to repeated treadmill-slip perturbations during stance in healthy young adults.

Abstract

Treadmill-based repeated perturbation training (PBT) induces motor adaptation in reactive balance responses, thus lowering the risk of slip-induced falls. However, little evidence exists regarding intervention-induced changes in neuromuscular control underlying motor adaptation. Examining neuromuscular changes could be an important step in identifying key elements of adaptation and evaluating treadmill training protocols for fall prevention. Moreover, identifying the muscle synergies contributing to motor adaptation in young adults could lay the groundwork for comparison with high fall-risk populations. Thus, we aimed to investigate neuromuscular changes in reactive balance responses during stance slip-PBT. Lower limb electromyography (EMG) signals (4/leg) were recorded during ten repeated forward stance (slip-like) perturbations in twenty-six young adults. Muscle synergies were compared between early-training (slips 1-2) and late-training (slips 9-10) stages. Results showed that 5 different modes of synergies (named on dominant muscles: W_TA, W_{S_VLAT}, W_{R_GAS}, W_{R_VLAT}, and W_{S_GAS}) were recruited in both stages. 3 out of 5 synergies (W_TA, W_{R_VLAT}, and W_{S_GAS}) showed a high similarity (r>0.97) in structure and activation between stages, whereas W_{R_GAS} and W_{S_VLAT} showed a lower similarity (r<0.83) between the two stages, and the area of activation in W_TA, the peak value of activation in W_{R_VLAT} and the activation onset in W_{R_GAS} showed a reduction from early-to late-training stage (p<0.05). These results suggest that a block of stance slip-PBT resulted in modest changes in muscle synergies in young adults, which might explain the smaller changes seen in biomechanical variables. Future studies should examine neuromuscular changes in people at high risk of falls.