Nature Communications (Nov 2024)

Revealing single-neuron and network-activity interaction by combining high-density microelectrode array and optogenetics

  • Toki Kobayashi,
  • Kenta Shimba,
  • Taiyo Narumi,
  • Takahiro Asahina,
  • Kiyoshi Kotani,
  • Yasuhiko Jimbo

DOI
https://doi.org/10.1038/s41467-024-53505-w
Journal volume & issue
Vol. 15, no. 1
pp. 1 – 13

Abstract

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Abstract The synchronous activity of neuronal networks is considered crucial for brain function. However, the interaction between single-neuron activity and network-wide activity remains poorly understood. This study explored this interaction within cultured networks of rat cortical neurons. Employing a combination of high-density microelectrode array recording and optogenetic stimulation, we established an experimental setup enabling simultaneous recording and stimulation at a precise single-neuron level that can be scaled to the level of the whole network. Leveraging our system, we identified a network burst-dependent response change in single neurons, providing a possible mechanism for the network-burst-dependent loss of information within the network and consequent cognitive impairment during epileptic seizures. Additionally, we directly recorded a leader neuron initiating a spontaneous network burst and characterized its firing properties, indicating that the bursting activity of hub neurons in the brain can initiate network-wide activity. Our study offers valuable insights into brain networks characterized by a combination of bottom-up self-organization and top-down regulation.