Sensory stimuli dominate over rhythmic electrical stimulation in modulating behavior.

IF 9.8 1区生物学 Q1 Agricultural and Biological Sciences

PLoS Biology Pub Date : 2025-06-05 eCollection Date: 2025-06-01 DOI:10.1371/journal.pbio.3003180

Yuranny Cabral-Calderin, Molly J Henry

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引用次数: 0

Abstract

Neural tracking (entrainment) of auditory rhythms enhances perception. We previously demonstrated that transcranial alternating current stimulation (tACS) can enhance or suppress entrainment to rhythmic auditory stimuli, depending on the timing between the electrical and auditory signals, although tACS effects are primarily modulatory. This study further investigated entrainment to tACS and auditory rhythms when the electrical and auditory signals were presented together (Experiment 1, N = 34) or independently (Experiment 2, N = 24; Experiment 3, N = 12). We hypothesized that tACS effects would be more pronounced when the auditory rhythm was made less perceptually salient to reduce the competition with the electrical rhythm. Participants detected silent gaps in modulated or unmodulated noise stimuli. In Experiment 1, auditory stimuli predominated in entraining behavior. While behavioral entrainment to sound rhythms was affected by the modulation depth of the auditory stimulus, entrainment to tACS was not. In Experiment 2, with no rhythmic information from the sound, 17 of 24 participants showed significant behavioral entrainment to tACS, although the most effective tACS frequency varied across participants. An oscillator model with a free parameter for the individual resonance frequency produced profiles similar to those we observed behaviorally. In Experiment 3, both neural and behavioral entrainment to rhythmic sounds were affected by the auditory stimulus frequency, but again the most effective entraining frequency varied across participants. Our findings suggest that tACS effects depend on the individual's preferred frequency when there is no competition with sensory stimuli, emphasizing the importance of targeting individual frequencies in tACS experiments. When both sensory and electrical stimuli are rhythmic and compete, sensory stimuli prevail, indicating the superiority of sensory stimulation in modulating behavior.

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在调节行为方面，感觉刺激比节律性电刺激占优势。

听觉节奏的神经追踪（附带）增强知觉。我们之前已经证明，经颅交流电刺激（tACS）可以增强或抑制有节奏的听觉刺激，这取决于电信号和听觉信号之间的时间，尽管tACS的作用主要是调节性的。本研究进一步探讨了电信号和听觉信号同时呈现（实验1，N = 34）或单独呈现(实验2，N = 24；实验3，N = 12)。我们假设，当听觉节奏在感知上不那么突出以减少与电节奏的竞争时，tACS效应会更加明显。参与者在调制或未调制的噪声刺激中检测到无声间隙。在实验1中，听觉刺激在诱导行为中占主导地位。听觉刺激的调制深度对声音节奏的行为夹带有影响，而对tACS的行为夹带不受影响。在实验2中，在没有声音节奏信息的情况下，24名参与者中有17人对tACS表现出显著的行为诱导，尽管最有效的tACS频率在参与者之间存在差异。单个共振频率具有自由参数的振荡器模型产生了与我们观察到的行为相似的轮廓。在实验3中，对节奏性声音的神经和行为诱导都受到听觉刺激频率的影响，但最有效的诱导频率在参与者之间也存在差异。我们的研究结果表明，在没有感官刺激竞争的情况下，tACS效应取决于个体偏好的频率，强调了tACS实验中针对个体频率的重要性。当感觉刺激和电刺激都有节奏且相互竞争时，感觉刺激占优势，表明感觉刺激在调节行为方面具有优势。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

PLoS Biology BIOCHEMISTRY & MOLECULAR BIOLOGY-BIOLOGY

CiteScore

15.40

自引率

2.00%

发文量

359

审稿时长

3-8 weeks

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