神経細胞の分散培養系の逸脱検出特性

カテゴリ: 論文誌(論文単位)

グループ名: 【C】電子・情報・システム部門

発行日: 2021/05/01

タイトル(英語): Deviance Detection Property in Dissociated Cultures of Neurons

著者名: 窪田　智之（東京大学大学院工学系研究科），櫻山　和浩（東京大学大学院情報理工学系研究科），白松(磯口)　知世（東京大学大学院情報理工学系研究科），高橋　宏知（東京大学大学院情報理工学系研究科）

著者名(英語): Tomoyuki Kubota (Graduate School of Engineering, The University of Tokyo), Kazuhiro Sakurayama (Graduate School of Information Science and Technology, The University of Tokyo), Tomoyo Isoguchi Shiramatsu (Graduate School of Information Science and Technol

キーワード: 逸脱検出特性，刺激選択的順応，神経細胞の分散培養系，微小電極アレイ　　deviance detection property，stimulus-specific adaptation，dissociated culture of neurons，microelectrode array

要約(英語): Evoked activities in the neural systems often depend on the event probabilities, suggesting that the neural systems have prediction capability based on the memory of stimulus history. Such prediction capability is often characterized as deviance detection property, which is not explained by the mere effect of stimulus specific adaptation. We here investigate whether neuronal dissociate culture, i.e., one of the most primitive neural circuits, exhibits deviance detection property as found in the higher-order sensory and association cortices. A high-dense CMOS electrode array measured neural activity patterns evoked by patterned electrical stimuli under either an oddball condition or many standards control (MSC) condition. Our results demonstrated the deviant-evoked neural activities were larger than the standard-evoked neural activities in the oddball condition and that the deviant stimulus evoked significantly larger activities in the oddball condition than in the MSC condition. Furthermore, these trends were more obvious in the late responses, which were mediated by a number of synapses, than in the early responses that were directly elicited by microstimulation. Thus, the present study showed the first evidence that the neuronal dissociate culture exhibits the deviance detection property, or the primitive intelligence.

本誌: 電気学会論文誌C（電子・情報・システム部門誌） Vol.141 No.5 （2021） 特集：神経工学

本誌掲載ページ: 661-667 p

原稿種別: 論文／日本語

電子版へのリンク: https://www.jstage.jst.go.jp/article/ieejeiss/141/5/141_661/_article/-char/ja/