A silicon diode-based optoelectronic interface for bidirectional neural modulation.
Xin FuZhengwei HuWenjun LiLiang MaJunyu ChenMuyang LiuJie LiuShuhan HuHuachun WangYunxiang HuangGuo TangBozhen ZhangXue CaiYuqi WangLizhu LiJian MaSong-Hai ShiLan YinHao ZhangXiaojian LiXing ShengPublished in: Proceedings of the National Academy of Sciences of the United States of America (2024)
The development of advanced neural modulation techniques is crucial to neuroscience research and neuroengineering applications. Recently, optical-based, nongenetic modulation approaches have been actively investigated to remotely interrogate the nervous system with high precision. Here, we show that a thin-film, silicon (Si)-based diode device is capable to bidirectionally regulate in vitro and in vivo neural activities upon adjusted illumination. When exposed to high-power and short-pulsed light, the Si diode generates photothermal effects, evoking neuron depolarization and enhancing intracellular calcium dynamics. Conversely, low-power and long-pulsed light on the Si diode hyperpolarizes neurons and reduces calcium activities. Furthermore, the Si diode film mounted on the brain of living mice can activate or suppress cortical activities under varied irradiation conditions. The presented material and device strategies reveal an innovated optoelectronic interface for precise neural modulations.
Keyphrases
- room temperature
- spinal cord
- high resolution
- type diabetes
- gene expression
- photodynamic therapy
- white matter
- drug delivery
- dna methylation
- mass spectrometry
- gold nanoparticles
- insulin resistance
- subarachnoid hemorrhage
- reactive oxygen species
- drug release
- high fat diet induced
- ionic liquid
- radiation induced
- atomic force microscopy