Frontiers in Neural Circuits (Oct 2013)

Optogenetic stimulation effectively enhances intrinsically generated network synchrony

  • Ahmed eEl Hady,
  • Ahmed eEl Hady,
  • Ahmed eEl Hady,
  • Ahmed eEl Hady,
  • Ghazaleh eAfshar,
  • Ghazaleh eAfshar,
  • Kai eBroeking,
  • Kai eBroeking,
  • Kai eBroeking,
  • Oliver eSchlüter,
  • Oliver eSchlüter,
  • Oliver eSchlüter,
  • Theo eGeisel,
  • Theo eGeisel,
  • Theo eGeisel,
  • Theo eGeisel,
  • Walter eStühmer,
  • Walter eStühmer,
  • Walter eStühmer,
  • Walter eStühmer,
  • Fred eWolf,
  • Fred eWolf,
  • Fred eWolf,
  • Fred eWolf,
  • Fred eWolf

DOI
https://doi.org/10.3389/fncir.2013.00167
Journal volume & issue
Vol. 7

Abstract

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Synchronized bursting is found in many brain areas and has also been implicated in the pathophysiology of neuropsychiatric disorders such as epilepsy, Parkinson’s disease and schizophrenia. Despite extensive studies of network burst synchronization, it is insufficiently understood how this type of network wide synchronization can be strengthened, reduced or even abolished. We combined electrical recording using multi-electrode array with optical stimulation of cultured channelrhodopsin-2 transducted hippocampal neurons to study and manipulate network burst synchronization. We found low frequency photo-stimulation protocols that are sufficient to induce potentiation of network bursting, modifying bursting dynamics and increasing interneuronal synchronization. Surprisingly, slowly fading-in light stimulation, which substantially delayed and reduced light driven spiking, was at least as effective in reorganizing network dynamics as much stronger pulsed light stimulation. Our study shows that mild stimulation protocols that do not enforce particular activity patterns onto the network can be highly effective inducers of network-level plasticity.

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