神经科学
颞叶
编码(内存)
海马结构
神经调节
经颅交流电刺激
脑刺激
刺激
心理学
大脑活动与冥想
召回
情景记忆
人脑
鼻周皮质
海马体
认知
大脑定位
工作记忆
神经网络
功能磁共振成像
颞叶皮质
新皮层
运动前神经元活动
皮质(解剖学)
脑深部刺激
大脑皮层
计算机科学
脑功能
干涉理论
磁刺激
作者
Florian Missey,Eva Jouval-Missey,Mariane de Araújo e Silva,Adryelle Arantes,Claudia Lubrano,Jan Trajlínek,Samuel Klus,Ondřej Studnička,Inês R. Violante,Mélanie Boly,Viktor Jirsa,Giulio Tononi,Nigel P. Pedersen,Daniel L. Drane,Adam Williamson
出处
期刊:
[Cold Spring Harbor Laboratory]
日期:2025-09-22
被引量:1
标识
DOI:10.1101/2025.09.22.677714
摘要
Visual memory relies on synchronized interactions and rhythms between the medial temporal lobes and neocortical brain regions. Non-invasive manipulation of memory-related brain regions, specifically deeper temporal lobe regions, has been limited by the lack of precision of non-invasive neuromodulation - when targeting deeper structures, the cortex is always stimulated, never deeper structures in isolation. Temporal Interference (TI) stimulation, a novel non-invasive technique, uses high-frequency carrier fields to deliver targeted, physiologically relevant neuromodulation via amplitude-modulated envelopes at specific brain regions. Here, we investigate TI's impact on figure memory encoding in 70 healthy participants using the Rey-Osterrieth and Taylor Complex Figure tasks, with TI applied in several brain regions independently and simultaneously - allowing investigation of combinations of medial temporal lobe and neocortical brain regions. Interestingly, higher frequency TI envelopes (130 Hz offset) targeting bilateral hippocampi and temporal cortices significantly impair recall (p = 6.54e-04), while lower frequency TI envelopes (5 Hz offset) targeting only the bilateral hippocampi significantly enhance recall (p = 0.0447). Stimulation using other combinations of medial temporal lobe and neocortical regions showed no effect, underscoring the critical role of frequency and focality of non-invasive brain stimulation and correct target selection. Finally, functional MRI reveals strong differences between the effects of 130 Hz and 5 Hz envelopes, specifically in hippocampal BOLD signals, brain connectivity, default mode, and attentional networks. These findings demonstrate TI's ability to bidirectionally modulate memory encoding through precise frequency and target tuning, offering a powerful tool for cognitive neuroscience and potential therapeutic applications for memory disorders.
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