用于神经活动光电激发与抑制的生物可吸收薄膜硅二极管。

Bioresorbable thin-film silicon diodes for the optoelectronic excitation and inhibition of neural activities.

作者信息

Huang Yunxiang, Cui Yuting, Deng Hanjie, Wang Jingjing, Hong Rongqi, Hu Shuhan, Hou Hanqing, Dong Yuanrui, Wang Huachun, Chen Junyu, Li Lizhu, Xie Yang, Sun Pengcheng, Fu Xin, Yin Lan, Xiong Wei, Shi Song-Hai, Luo Minmin, Wang Shirong, Li Xiaojian, Sheng Xing

机构信息

Department of Electronic Engineering, Beijing National Research Center for Information Science and Technology, Institute for Precision Medicine, Center for Flexible Electronics Technology, Tsinghua University, Beijing, China.

School of Materials Science and Engineering, The Key Laboratory of Advanced Materials of Ministry of Education, State Key Laboratory of New Ceramics and Fine Processing, Center for Flexible Electronics Technology, Tsinghua University, Beijing, China.

出版信息

Nat Biomed Eng. 2023 Apr;7(4):486-498. doi: 10.1038/s41551-022-00931-0. Epub 2022 Sep 5.

DOI:10.1038/s41551-022-00931-0

PMID:36065014

Abstract

Neural activities can be modulated by leveraging light-responsive nanomaterials as interfaces for exerting photothermal, photoelectrochemical or photocapacitive effects on neurons or neural tissues. Here we show that bioresorbable thin-film monocrystalline silicon pn diodes can be used to optoelectronically excite or inhibit neural activities by establishing polarity-dependent positive or negative photovoltages at the semiconductor/solution interface. Under laser illumination, the silicon-diode optoelectronic interfaces allowed for the deterministic depolarization or hyperpolarization of cultured neurons as well as the upregulated or downregulated intracellular calcium dynamics. The optoelectronic interfaces can also be mounted on nerve tissue to activate or silence neural activities in peripheral and central nervous tissues, as we show in mice with exposed sciatic nerves and somatosensory cortices. Bioresorbable silicon-based optoelectronic thin films that selectively excite or inhibit neural tissue may find advantageous biomedical applicability.

摘要

通过利用光响应性纳米材料作为界面，对神经元或神经组织施加光热、光电化学或光电电容效应，可以调节神经活动。在这里，我们展示了可生物吸收的薄膜单晶硅pn二极管可用于通过在半导体/溶液界面建立极性依赖的正或负光电压来光电激发或抑制神经活动。在激光照射下，硅二极管光电界面能够确定性地使培养的神经元去极化或超极化，以及上调或下调细胞内钙动力学。如我们在暴露坐骨神经和体感皮层的小鼠中所示，光电界面还可以安装在神经组织上，以激活或沉默外周和中枢神经组织中的神经活动。选择性激发或抑制神经组织的可生物吸收硅基光电薄膜可能具有有利的生物医学应用前景。

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用于神经活动光电激发与抑制的生物可吸收薄膜硅二极管。

Bioresorbable thin-film silicon diodes for the optoelectronic excitation and inhibition of neural activities.

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