Department of Rehabilitation Medicine, Nowon Eulji Medical Center, Eulji University, Seoul, Republic of Korea.
Department of Biomedical Engineering, College of medicine, Keimyung University, Daegu, Republic of Korea.
J Neural Eng. 2022 Jun 20;19(3). doi: 10.1088/1741-2552/ac76e0.
Action observation (AO) combined with brain-computer interface (BCI) technology enhances cortical activation. Peripheral electrical stimulation (PES) increases corticospinal excitability, thereby activating brain plasticity. To maximize motor recovery, we assessed the effects of BCI-AO combined with PES on corticospinal plasticity.Seventeen patients with chronic hemiplegic stroke and 17 healthy subjects were recruited. The participants watched a video of repetitive grasping actions with four different tasks for 15 min: (A) AO alone; (B) AO + PES; (C) BCI-AO + continuous PES; and (D) BCI-AO + triggered PES. PES was applied at the ulnar nerve of the wrist. The tasks were performed in a random order at least three days apart. We assessed the latency and amplitude of motor evoked potentials (MEPs). We examined changes in MEP parameters pre-and post-exercise across the four tasks in the first dorsal interosseous muscle of the dominant hand (healthy subjects) and affected hand (stroke patients).The decrease in MEP latency and increase in MEP amplitude after the four tasks were significant in both groups. The increase in MEP amplitude was sustained for 20 min after tasks B, C, and D in both groups. The increase in MEP amplitude was significant between tasks A vs. B, B vs. C, and C vs. D. The estimated mean difference in MEP amplitude post-exercise was the highest for A and D in both groups.The results indicate that BCI-AO combined with PES is superior to AO alone or AO + PES for facilitating corticospinal plasticity in both healthy subjects and patients with stroke. Furthermore, this study supports the idea that synchronized activation of cortical and peripheral networks can enhance neuroplasticity after stroke. We suggest that the BCI-AO paradigm and PES could provide a novel neurorehabilitation strategy for patients with stroke.
动作观察(AO)与脑机接口(BCI)技术相结合可增强皮质激活。外周电刺激(PES)增加皮质脊髓兴奋性,从而激活大脑可塑性。为了最大限度地促进运动功能恢复,我们评估了 BCI-AO 与 PES 联合应用对皮质脊髓可塑性的影响。
共招募 17 例慢性偏瘫脑卒中患者和 17 名健康受试者。参与者观看重复抓握动作视频,完成 4 项不同任务 15 分钟:(A)单独 AO;(B)AO+PES;(C)BCI-AO+连续 PES;(D)BCI-AO+触发 PES。PES 施加于腕部尺神经。任务以至少相隔 3 天的随机顺序进行。我们评估运动诱发电位(MEP)的潜伏期和振幅。我们在健康受试者的优势手(第一背侧骨间肌)和脑卒中患者的患手检查了 4 项任务前后 MEP 参数的变化。
在两组中,4 项任务后 MEP 潜伏期缩短,MEP 振幅增加,均有统计学意义。两组在任务 B、C 和 D 后,MEP 振幅增加持续 20 分钟。任务 A 与 B、B 与 C、C 与 D 之间 MEP 振幅增加有统计学差异。两组运动后 MEP 振幅增加的估计平均差异在任务 A 和 D 中最高。
结果表明,BCI-AO 与 PES 联合应用优于单独 AO 或 AO+PES,可促进健康受试者和脑卒中患者的皮质脊髓可塑性。此外,本研究支持皮质和外周网络同步激活可增强脑卒中后神经可塑性的观点。我们建议 BCI-AO 范式和 PES 可为脑卒中患者提供新的神经康复策略。
