Ian M. Stanford scite author profile

Synchronous neuronal oscillations in the 30-70 Hz range, known as gamma oscillations, occur in the cortex of many species. This synchronization can occur over large distances, and in some cases over multiple cortical areas and in both hemispheres; it has been proposed to underlie the binding of several features into a single perceptual entity. The mechanism by which coherent oscillations are generated remains unclear, because they often show zero or near-zero phase lags over long distances, whereas much greater phase lags would be expected from the slow speed of axonal conduction. We have previously shown that interneuron networks alone can generate gamma oscillations; here we propose a simple model to explain how an interconnected chain of such networks can generate coherent oscillations. The model incorporates known properties of excitatory pyramidal cells and inhibitory interneurons; it predicts that when excitation of interneurons reaches a level sufficient to induce pairs of spikes in rapid succession (spike doublets), the network will generate gamma oscillations that are synchronized on a millisecond time-scale from one end of the chain to the other. We show that in rat hippocampal slices interneurons do indeed fire spike doublets under conditions in which gamma oscillations are synchronized over several millimetres, whereas they fire single spikes under other conditions. Thus, known properties of neurons and local synaptic circuits can account for tightly synchronized oscillations in large neuronal ensembles.

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The role of GABAergic modulation in motor function related neuronal network activity

Hall

et al. 2011

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Spatiotemporal patterns of γ frequency oscillations tetanically induced in the rat hippocampal slice

Whittington

Stanford

Colling

et al. 1997

The Journal of Physiology

210

204

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We used transverse and longitudinal rat hippocampal slices to study the synchronization of γ frequency (> 20 Hz) oscillations, across distances of up to 4.5 mm. γ oscillations were evoked in the CA1 region by tetanic stimulation at one or two sites simultaneously, and were associated with population spikes. Tetanic stimuli that were strong enough to induce oscillations were associated with depolarization of both pyramidal cells and interneurones, largely produced by activation of metabotropic glutamate receptors. Computer simulations of γ oscillations were also performed in a model with pyramidal cells and interneurones, arranged in a chain of five cell groups. This model had suggested previously that interneurone networks alone could generate synchronous γ oscillations locally, but that pyramidal cell firing, by inducing spike doublets in interneurones, was necessary for the occurrence of highly correlated oscillations with small phase lag (< 2.5 ms), in a distributed network possessing long axon conduction delays. In both experiment and model, pyramidal cell spikes occurred in phase with local population spikes, as did the first spike of the interneurone doublet. The conductance of the interneurone α‐amino‐3‐hydroxy‐5‐methyl‐4‐isoxazole propionic acid (AMPA) receptor‐mediated conductance was manipulated in the model, while the relation between oscillations at opposite ends of the chain was examined. When the conductance was large enough for doublet firing to be synaptically induced in interneurones, oscillation phase lags were < 2.25 ms across the chain. As predicted, experimental blockade of AMPA receptors resulted in increased phase lags between two sites oscillating simultaneously, compared with control conditions. Both in model and in experiment, when stimuli to the two ends of the network were slightly different, cross‐network synchronization occurred with a shorter phase lag at high frequencies than at lower frequencies. These data suggest that, while interneurone networks alone can generate locally synchronized γ oscillations, firing of pyramidal cells, and the synaptically induced doublet firing in interneurones, contribute to the stability and tight synchrony of the oscillations in distributed networks.

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Electrophysiological and morphological characteristics of three subtypes of rat globus pallidus neurone in vitro

Cooper

Stanford

2000

The Journal of Physiology

213

176

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1. Neurones of the globus pallidus (GP) have been classified into three subgroups based on the visual inspection of current clamp electrophysiological properties and morphology of biocytin-filled neurones. 2. Type A neurones (132Ï208; 63%) were identified by the presence of the time-and voltagedependent inward rectifier (Ih) and the low-threshold calcium current (It) giving rise to anodal break depolarisations. These cells were quiescent or fired regular spontaneous action potentials followed by biphasic AHPs. Current injection evoked regular activity up to maximum firing frequency of 350 Hz followed by moderate spike frequency adaptation. The somata of type A cells were variable in shape (20 ² 12 ìm) while their dendrites were highly varicose. 3. Type B neurones (66Ï208; 32%) exhibited neither Ih nor rebound depolarisations and only a fast monophasic AHP. These cells were spontaneously active while current injection induced irregular patterns of action potential firing up to a frequency of 440 Hz with weak spike frequency adaptation. Morphologically, these cells were the smallest encountered (15 ² 10 ìm), oval in shape with restricted varicose dendritic arborisations. 4. Type C neurones were much rarer (10Ï208; 5%). They were identified by the absence of Ih and rebound depolarisations, but did possess a prolonged biphasic AHP. They displayed large A-like potassium currents and ramp-like depolarisations in response to step current injections, which induced firing up to a maximum firing frequency of 310 Hz. These cells were the largest observed (27 ² 15 ìm) with extensive dendritic branching. 5. These results confirm neuronal heterogeneity in the adult rodent GP. The driven activity and population percentage of the three subtypes correlates well with the in vivo studies (Kita & Kitai, 1991). Type A cells appear to correspond to type II neurones of Nambu & Llinas (1994, 1997 while the small diameter type B cells display morphological similarities with those described by Millhouse (1986). The rarely encountered type C cells may well be large cholinergic neurones. These findings provide a cellular basis for the study of intercellular communication and network interactions in the adult rat in vitro. Keywords:

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Pharmacologically induced and stimulus evoked rhythmic neuronal oscillatory activity in the primary motor cortex in vitro

et al. 2008

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Ian M. Stanford

A mechanism for generation of long-range synchronous fast oscillations in the cortex

The role of GABAergic modulation in motor function related neuronal network activity

Spatiotemporal patterns of γ frequency oscillations tetanically induced in the rat hippocampal slice

Electrophysiological and morphological characteristics of three subtypes of rat globus pallidus neurone in vitro

Pharmacologically induced and stimulus evoked rhythmic neuronal oscillatory activity in the primary motor cortex in vitro

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