The University of Texas at Dallas, School of Behavioral Brain Sciences, Richardson, TX, United States; The University of Texas at Dallas, Texas Biomedical Device Center, Richardson, TX, United States.
The University of Texas at Dallas, Texas Biomedical Device Center, Richardson, TX, United States.
Behav Brain Res. 2020 Aug 5;391:112705. doi: 10.1016/j.bbr.2020.112705. Epub 2020 May 28.
Pairing vagus nerve stimulation (VNS) with rehabilitation has emerged as a potential strategy to improve recovery after neurological injury, an effect ascribed to VNS-dependent enhancement of synaptic plasticity. Previous studies demonstrate that pairing VNS with forelimb training increases forelimb movement representations in motor cortex. However, it is not known whether VNS-dependent enhancement of plasticity is restricted to forelimb training or whether VNS paired with other movements could induce plasticity of other motor representations. We tested the hypothesis that VNS paired with orofacial movements associated with chewing during an unskilled task would drive a specific increase in jaw representation in motor cortex compared to equivalent behavioral experience without VNS. Rats performed a behavioral task in which VNS at a specified intensity between 0 and 1.2 mA was paired with chewing 200 times per day for five days. Intracortical microstimulation (ICMS) was then used to document movement representations in motor cortex. VNS paired with chewing at 0.8 mA significantly increased motor cortex jaw representation compared to equivalent behavioral training without stimulation (Bonferroni-corrected unpaired t-test, p < 0.01). Higher and lower intensities failed to alter cortical plasticity. No changes in other movement representations or total motor cortex area were observed between groups. These results demonstrate that 0.8 mA VNS paired with training drives robust plasticity specific to the paired movement, is not restricted to forelimb representations, and occurs with training on an unskilled task. This suggests that moderate intensity VNS may be a useful adjuvant to enhance plasticity and support benefits of rehabilitative therapies targeting functions beyond upper limb movement.
迷走神经刺激(VNS)与康复相结合已成为一种改善神经损伤后恢复的潜在策略,其效果归因于 VNS 依赖性增强突触可塑性。先前的研究表明,将 VNS 与前肢训练相结合可以增加运动皮层中前肢运动的代表。然而,目前尚不清楚 VNS 依赖性的可塑性增强是否仅限于前肢训练,或者 VNS 与其他运动相结合是否可以诱导其他运动代表的可塑性。我们测试了这样一个假设,即 VNS 与与咀嚼相关的口腔运动相结合,在一项非熟练任务中,与没有 VNS 的等效行为经验相比,会导致运动皮层中下颌代表的特异性增加。大鼠进行了一项行为任务,其中在 0 到 1.2 mA 之间的特定强度下进行 VNS,每天与咀嚼 200 次配对,持续五天。然后使用皮质内微刺激(ICMS)记录运动皮层中的运动代表。与 0.8 mA 的咀嚼配对的 VNS 显著增加了运动皮层的下颌代表,与没有刺激的等效行为训练相比(经 Bonferroni 校正的未配对 t 检验,p <0.01)。较高和较低的强度未能改变皮质可塑性。两组之间未观察到其他运动代表或总运动皮层面积的变化。这些结果表明,0.8 mA 的 VNS 与训练配对可驱动与配对运动特异性的强大可塑性,不限于前肢代表,并且发生在非熟练任务的训练上。这表明中等强度的 VNS 可能是增强可塑性和支持针对上肢运动以外的功能的康复治疗益处的有用辅助手段。