利用经颅交流电刺激增强动态视敏度。

IF 4.7 2区 心理学 Q1 BEHAVIORAL SCIENCES
Jimin Park, Sangjun Lee, Dasom Choi, Chang-Hwan Im
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引用次数: 0

摘要

背景:在高阶认知过程中,皮层振荡的交叉频率相幅耦合(PAC)在皮层区域内和跨皮层区域被观察到。特别是,枕叶皮层的α和γ波的PAC与视觉感知密切相关。理论上,伽马振荡是视觉刺激的一种神经元表征,它与α振荡一起驱动视觉感知的占空比。因此,我们认为,α - γ PAC的夹带时间可能在视觉感知的表现中起着关键作用。我们假设经颅交流电刺激(tACS)在α波波谷处携带γ波可以提高动态视力(DVA)。方法:尝试用tACS调节DVA的性能。tACS的波形是针对枕皮质上的PAC进行定制的。波形包含伽马(80赫兹)波在α(10赫兹)波的波峰或波谷处振荡。参与者在每次刺激前、刺激后和刺激后10分钟分别执行计算机化DVA任务。在DVA任务中记录EEG和EOG以评估试验间相相干性(ITPC)、枕部α - γ PAC和眼动。结果:波谷带波的tACS能有效增强DVA,波峰带波的tACS对DVA无影响。重要的是,脑电图和脑电图的分析表明,DVA性能的增强完全源于神经调节作用,而与跳眼运动的调节无关。因此,DVA作为一种高阶认知能力,被tACS成功地调制成一种定制的波形。结论:我们的实验结果表明,当在枕皮质上施加带有α波谷的伽马脉冲的tACS时,DVA的性能得到了增强。我们的研究结果表明,使用具有定制波形的tACS,调制复杂的神经元特征可以有效地增强DVA等高阶认知能力,这是传统的无创脑刺激方法从未调节过的。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Enhancement of dynamic visual acuity using transcranial alternating current stimulation with gamma burst entrained on alpha wave troughs.

Enhancement of dynamic visual acuity using transcranial alternating current stimulation with gamma burst entrained on alpha wave troughs.

Enhancement of dynamic visual acuity using transcranial alternating current stimulation with gamma burst entrained on alpha wave troughs.

Enhancement of dynamic visual acuity using transcranial alternating current stimulation with gamma burst entrained on alpha wave troughs.

Background: Cross-frequency phase-amplitude coupling (PAC) of cortical oscillations is observed within and across cortical regions during higher-order cognitive processes. Particularly, the PAC of alpha and gamma waves in the occipital cortex is closely associated with visual perception. In theory, gamma oscillation is a neuronal representation of visual stimuli, which drives the duty cycle of visual perception together with alpha oscillation. Therefore, it is believed that the timing of entrainment in alpha-gamma PAC may play a critical role in the performance of visual perception. We hypothesized that transcranial alternating current stimulation (tACS) with gamma waves entrained at the troughs of alpha waves would enhance the dynamic visual acuity (DVA).

Method: We attempted to modulate the performance of DVA by using tACS. The waveforms of the tACS were tailored to target PAC over the occipital cortex. The waveforms contained gamma (80 Hz) waves oscillating at either the peaks or troughs of alpha (10 Hz) waves. Participants performed computerized DVA task before, immediately after, and 10 min after each stimulation sessions. EEG and EOG were recorded during the DVA task to assess inter-trial phase coherence (ITPC), the alpha-gamma PAC at occipital site and the eye movements.

Results: tACS with gamma waves entrained at alpha troughs effectively enhanced DVA, while the tACS with gamma waves entrained at alpha peaks did not affect DVA performance. Importantly, analyses of EEG and EOG showed that the enhancement of DVA performance originated solely from the neuromodulatory effects, and was not related to the modulation of saccadic eye movements. Consequently, DVA, one of the higher-order cognitive abilities, was successfully modulated using tACS with a tailored waveform.

Conclusions: Our experimental results demonstrated that DVA performances were enhanced when tACS with gamma bursts entrained on alpha wave troughs were applied over the occipital cortex. Our findings suggest that using tACS with tailored waveforms, modulation of complex neuronal features could effectively enhance higher-order cognitive abilities such as DVA, which has never been modulated with conventional noninvasive brain stimulation methods.

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来源期刊
Behavioral and Brain Functions
Behavioral and Brain Functions 医学-行为科学
CiteScore
5.90
自引率
0.00%
发文量
11
审稿时长
6-12 weeks
期刊介绍: A well-established journal in the field of behavioral and cognitive neuroscience, Behavioral and Brain Functions welcomes manuscripts which provide insight into the neurobiological mechanisms underlying behavior and brain function, or dysfunction. The journal gives priority to manuscripts that combine both neurobiology and behavior in a non-clinical manner.
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