Single Neurons Can Induce Phase Transitions of Cortical Recurrent Networks with Multiple Internal States

doi:10.1093/cercor/bhj010

Cerebral Cortex Advance Access published online on August 10, 2005
Cerebral Cortex, doi:10.1093/cercor/bhj010

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© The Author 2005. Published by Oxford University Press. All rights reserved. For permissions, please e-mail: journals.permissions@oupjournals.org

Article

Single Neurons Can Induce Phase Transitions of Cortical Recurrent Networks with Multiple Internal States

Shigeyoshi Fujisawa ¹, Norio Matsuki ¹, and Yuji Ikegaya ¹^*

¹ Laboratory of Chemical Pharmacology, Graduate School of Pharmaceutical Sciences, The University of Tokyo, Tokyo 113-0033, Japan

^* To whom correspondence should be addressed.
Yuji Ikegaya, E-mail: ikegaya{at}tk.air.jp

Abstract

Fluctuations of membrane potential of cortical neurons, referredto here as internal states, are essential for brain function,but little is known about how these internal states emerge andare maintained, or what determines transitions between thesestates. We performed intracellular recordings from hippocampalCA3 pyramidal cells ex vivo and found that neurons display multipleand hierarchical internal states, which are linked to cholinergicactivity and are characterized by several power law structuresin membrane potential dynamics. Multiple recordings from adjacentneurons revealed that the internal states were coherent betweenneurons, indicating that the internal state of any given cellin a local network could represent the network activity state.Repeated stimulation of single neurons led over time to transitionsto different internal states in both the stimulated neuron andneighboring neurons. Thus, single-cell activation is sufficientto shift the state of the entire local network. As the statesshift to more active levels, theta- and gamma-frequency componentsdeveloped in the form of subthreshold oscillations. State transitionswere associated with changes in membrane conductance but werenot accompanied by a change in reversal potential. These datasuggest that the recurrent network organizes the internal statesof individual neurons into synchronization through network activitywith balanced excitation and inhibition, and that this organizationis discrete, heterogeneous and dynamic in nature. Thus, neuronalstates reflect the ‘phase’ of an active network, anovel demonstration of the dynamics and flexibility of corticalmicrocircuitry.

Keywords: hippocampus; microcircuit; phase transition; recurrent network; self-organization; UP state.

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