Ultra-fast photoelectron transfer in bimetallic porphyrin optoelectrode for single neuron modulation

Jian Chen; Feixiang Chen; Xueli Wang; Hongjun Zhuang; Mengnan Guo; Luo Wang; Junze Xie; Le Zhang; Hao Liu; Yuhan Shi; Jiajia Zhou; Xinjie Mao; Muyao Lv; Xingwu Jiang; Jinquan Chen; Yanyan Liu; Dayong Jin; Wenbo Bu

doi:10.1038/s41467-024-54325-8

Ultra-fast photoelectron transfer in bimetallic porphyrin optoelectrode for single neuron modulation

Jian Chen
, Feixiang Chen
, Xueli Wang
, Hongjun Zhuang
, Mengnan Guo
, Luo Wang
, Junze Xie
, Le Zhang
, Hao Liu
, Yuhan Shi
, Jiajia Zhou
, Xinjie Mao
, Muyao Lv
, Xingwu Jiang
, Jinquan Chen^*
, Yanyan Liu^*
, Dayong Jin^*
, Wenbo Bu^*

^*Corresponding author for this work

Institute for Advanced Study in Precision Spectroscopy

Research output: Contribution to journal › Article › peer-review

5 Scopus citations

Abstract

Shrinking the size of photoelectrodes into the nanoscale will enable the precise modulation of cellular and subcellular behaviors of a single neuron and neural circuits. However, compared to photovoltaic devices, the reduced size causes the compromised efficiencies. Here, we present a highly efficient nanoelectrode based on bimetallic zinc and gold porphyrin (ZnAuPN). Upon light excitation, we observe ultrafast energy transfer (~66 ps) and charge transfer (~0.5 ps) through the porphyrin ring, enabling 97% efficiency in separating and transferring photoinduced charges to single Au-atom centers. Leveraging these isolated Au atoms as stimulating electrode arrays, we achieve significant photocurrent injection in single neurons, triggering action potential with millisecond light pulses. Notably, Extracranial near-infrared light irradiation of the motor cortex induces neuronal firing and enhances mouse movement. These results show the potential of nanoscale optoelectrodes for high spatiotemporal modulation of neuronal networks without the need for gene transfection in optogenetics.

Original language	English
Article number	10241
Journal	Nature Communications
Volume	15
Issue number	1
DOIs	https://doi.org/10.1038/s41467-024-54325-8
State	Published - Dec 2024

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Chen, J., Chen, F., Wang, X., Zhuang, H., Guo, M., Wang, L., Xie, J., Zhang, L., Liu, H., Shi, Y., Zhou, J., Mao, X., Lv, M., Jiang, X., Chen, J., Liu, Y., Jin, D., & Bu, W. (2024). Ultra-fast photoelectron transfer in bimetallic porphyrin optoelectrode for single neuron modulation. Nature Communications, 15(1), Article 10241. https://doi.org/10.1038/s41467-024-54325-8

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title = "Ultra-fast photoelectron transfer in bimetallic porphyrin optoelectrode for single neuron modulation",

abstract = "Shrinking the size of photoelectrodes into the nanoscale will enable the precise modulation of cellular and subcellular behaviors of a single neuron and neural circuits. However, compared to photovoltaic devices, the reduced size causes the compromised efficiencies. Here, we present a highly efficient nanoelectrode based on bimetallic zinc and gold porphyrin (ZnAuPN). Upon light excitation, we observe ultrafast energy transfer (\textasciitilde{}66 ps) and charge transfer (\textasciitilde{}0.5 ps) through the porphyrin ring, enabling 97\% efficiency in separating and transferring photoinduced charges to single Au-atom centers. Leveraging these isolated Au atoms as stimulating electrode arrays, we achieve significant photocurrent injection in single neurons, triggering action potential with millisecond light pulses. Notably, Extracranial near-infrared light irradiation of the motor cortex induces neuronal firing and enhances mouse movement. These results show the potential of nanoscale optoelectrodes for high spatiotemporal modulation of neuronal networks without the need for gene transfection in optogenetics.",

author = "Jian Chen and Feixiang Chen and Xueli Wang and Hongjun Zhuang and Mengnan Guo and Luo Wang and Junze Xie and Le Zhang and Hao Liu and Yuhan Shi and Jiajia Zhou and Xinjie Mao and Muyao Lv and Xingwu Jiang and Jinquan Chen and Yanyan Liu and Dayong Jin and Wenbo Bu",

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doi = "10.1038/s41467-024-54325-8",

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AU - Chen, Jian

AU - Chen, Feixiang

AU - Wang, Xueli

AU - Zhuang, Hongjun

AU - Guo, Mengnan

AU - Wang, Luo

AU - Xie, Junze

AU - Zhang, Le

AU - Liu, Hao

AU - Shi, Yuhan

AU - Zhou, Jiajia

AU - Mao, Xinjie

AU - Lv, Muyao

AU - Jiang, Xingwu

AU - Chen, Jinquan

AU - Liu, Yanyan

AU - Jin, Dayong

AU - Bu, Wenbo

PY - 2024/12

Y1 - 2024/12

N2 - Shrinking the size of photoelectrodes into the nanoscale will enable the precise modulation of cellular and subcellular behaviors of a single neuron and neural circuits. However, compared to photovoltaic devices, the reduced size causes the compromised efficiencies. Here, we present a highly efficient nanoelectrode based on bimetallic zinc and gold porphyrin (ZnAuPN). Upon light excitation, we observe ultrafast energy transfer (~66 ps) and charge transfer (~0.5 ps) through the porphyrin ring, enabling 97% efficiency in separating and transferring photoinduced charges to single Au-atom centers. Leveraging these isolated Au atoms as stimulating electrode arrays, we achieve significant photocurrent injection in single neurons, triggering action potential with millisecond light pulses. Notably, Extracranial near-infrared light irradiation of the motor cortex induces neuronal firing and enhances mouse movement. These results show the potential of nanoscale optoelectrodes for high spatiotemporal modulation of neuronal networks without the need for gene transfection in optogenetics.

AB - Shrinking the size of photoelectrodes into the nanoscale will enable the precise modulation of cellular and subcellular behaviors of a single neuron and neural circuits. However, compared to photovoltaic devices, the reduced size causes the compromised efficiencies. Here, we present a highly efficient nanoelectrode based on bimetallic zinc and gold porphyrin (ZnAuPN). Upon light excitation, we observe ultrafast energy transfer (~66 ps) and charge transfer (~0.5 ps) through the porphyrin ring, enabling 97% efficiency in separating and transferring photoinduced charges to single Au-atom centers. Leveraging these isolated Au atoms as stimulating electrode arrays, we achieve significant photocurrent injection in single neurons, triggering action potential with millisecond light pulses. Notably, Extracranial near-infrared light irradiation of the motor cortex induces neuronal firing and enhances mouse movement. These results show the potential of nanoscale optoelectrodes for high spatiotemporal modulation of neuronal networks without the need for gene transfection in optogenetics.

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DO - 10.1038/s41467-024-54325-8

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AN - SCOPUS:85210252650

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VL - 15

JO - Nature Communications

JF - Nature Communications

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ER -

Ultra-fast photoelectron transfer in bimetallic porphyrin optoelectrode for single neuron modulation

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