Brain oscillations provide framework for a neural syntax Most, if not all, network oscillations are based on inhibition wherein populations of principal neurons are paced by repetitive trains of inhibitory postsynaptic potentials. These rhythmic inhibitory volleys provide windows of alternating reduced and enhanced excitability of principal cells in a temporally coordinated manner.17,45 Indeed, segregation of excitatory principal cells into functional groups, often referred to as cell assemblies and assembly sequences,46 is perhaps the most important service performed by the

large family of inhibitory neuron classes Inhibitors,research,lifescience,medical in the cortex.47,48 Inhibition-based oscillations may do so by providing a natural means to “stop” signals of neuronal information flow by temporally silencing principal cells and “chunking” selleck chemicals Axitinib streams of messages into shorter frames, as evidenced by the observation that oscillations have well-defined Inhibitors,research,lifescience,medical onsets and offsets with characteristic Inhibitors,research,lifescience,medical maximum and minimum spiking activity in the information-transmitting principal

cells.49 This stop-start parsing function of neuronal oscillators and their hierarchical cross-frequency coupling organization (see section below as well as Figure 2), in turn, can support syntactical rules, known to both sender and receiver, making communication Inhibitors,research,lifescience,medical more OSI-744 straightforward than interpreting long

uninterrupted messages50 or stochastic patterns of spikes. In general, syntax is a set of principles that allows the generation of rich combinations from a limited number of elements using a minimal number of rules. It has been hypothesized that the Inhibitors,research,lifescience,medical fundamental element of neuronal syntax is an assembly of neurons discharging together in a γ cycle.51-53 The most important role of the cell assembly is to bring together sufficient numbers of peer neurons so that their collective spiking can bring above discharge threshold the proper population of downstream postsynaptic neurons.52 Consequently, from the point of view Anacetrapib of the downstream (“reader” or “integrator”) target cells, collective activity of upstream neurons is classified as a single event53 only if their spikes occur within the time-integrating window (ie, within the membrane time constant of the neurons, tends to be 10 to 30 msec; if signals occur within this time scale, they will be combined as a unitary event).54 Spikes of upstream neurons which fire outside the integration time window must be part of another event, or a separate assembly.