Spike Synchronization and Rate Modulation Differentially Involved in Motor Cortical Function

Riehle, Alexa; Grün, Sonja; Diesmann, Markus; Aertsen, Ad

doi:10.1126/science.278.5345.1950

Cited by 851 publications

(685 citation statements)

References 32 publications

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“…In the present study, the PM/MI neurons were trained similarly to the monkeys in the previous experiments (Riehle et al 1997(Riehle et al , 2000, as described below. In each learning trial, a cue signal appears at 100 msec to initiate the timed spikes.…”

Section: Resultsmentioning

confidence: 99%

“…Recent studies show that rate changes and synchronous firing of cortical neurons differentially engage in these cognitive functions. Riehle et al (1997) trained monkeys on a delayed response task in which a GO signal to instruct a motor response repeatedly followed a sensory cue at several possible, fixed delays. Spikes from pairs of premotor and primary motor (PM/MI) neurons coincided more frequently than expected by chance, particularly at those times when the monkeys were expecting the GO signal.…”

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confidence: 99%

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Temporal Characteristics of the Predictive Synchronous Firing Modeled by Spike-Timing-Dependent Plasticity

Kitano

Fukai²

2004

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When a sensory cue was repeatedly followed by a behavioral event with fixed delays, pairs of premotor and primary motor neurons showed significant increases of coincident spikes at times a monkey was expecting the event. These results provided evidence that neuronal firing synchrony has predictive power. To elucidate the underlying mechanism, here we argue some nontrivial characteristics of the predictive synchronous firing developed by spike-timing-dependent plasticity in a paradigm similar to classical conditioning. We find that the computationally developed synchrony shows the modulations of temporal precision, which are quite similar to those observed experimentally. Thus, our model suggests that the important characteristics of predictive synchronous firing, which were previously attributed to an animal's higher cognitive function, can emerge from a synaptic-level mechanism.It is clearly advantageous for animals to detect and remember the causal relationships between events, to predict their occurrence and to prepare for a response (Barto et al. 1983;Desmond and Moore 1988: Tanji andShima 1994;Schultz et al. 1997;Schultz 1998). Recent studies show that rate changes and synchronous firing of cortical neurons differentially engage in these cognitive functions. Riehle et al. (1997) trained monkeys on a delayed response task in which a GO signal to instruct a motor response repeatedly followed a sensory cue at several possible, fixed delays. Spikes from pairs of premotor and primary motor (PM/MI) neurons coincided more frequently than expected by chance, particularly at those times when the monkeys were expecting the GO signal. If the GO signal was actually presented at one of those times, the synchronous firing was followed by rate modulations.

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Section: Resultsmentioning

confidence: 99%

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confidence: 99%

Temporal Characteristics of the Predictive Synchronous Firing Modeled by Spike-Timing-Dependent Plasticity

Kitano

Fukai²

2004

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“…Numerical simulations of FFNs showed that excitation of the first group of neurons with a volley of near synchronous spikes may result in increased synchrony of the spike volley, which remains stable in subsequent layers (Diesmann et al, 1999). Thus, propagating synchrony in the FFN has been proposed as a model to explain the occurrence of task-related precise spike patterns observed in behaving primates (Abeles et al, 1993;Nicolelis et al, 1995;Riehle et al, 1997;Prut et al, 1998). Asynchronous firing rates can be propagated through the FFN only in a restricted parameter regime (van Rossum et al, 2002), as the significant amount of shared connectivity among the neurons tends to synchronize the activity from one group to the next (Litvak et al, 2003).…”

Section: Introductionmentioning

confidence: 99%

Conditions for Propagating Synchronous Spiking and Asynchronous Firing Rates in a Cortical Network Model

Kumar

Rotter²,

Aertsen³

2008

J. Neurosci.

185

246

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. Here, we show that by modeling synapses as conductance transients, rather than current sources, it is possible to embed and propagate transient synchrony in the FFN, without destabilizing the background network dynamics. However, the network activity has a strong impact on the type of activity that can be propagated in the embedded FFN. Global synchrony and high firing rates in the embedding network prohibit the propagation of both, synchronous and asynchronous spiking activity. In contrast, asynchronous low-rate network states support the propagation of both, synchronous spiking and asynchronous, but only low firing rates. In either case, spiking activity tends to synchronize as it propagates, challenging the feasibility to transmit information in asynchronous firing rates. Finally, asynchronous network activity allows to embed more than one FFN, with the amount of cross talk depending on the degree of overlap in the FFNs. This opens the possibility of computational mechanisms using transient synchrony among the activities in multiple FFNs.

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“…A particularly important application in this respect concerns their use as control measurements against which to test multiple single-unit spike data for the presence of dynamic spike synchronization phenomena (Gerstein and Aertsen, 1985;Aertsen et al, 1987Aertsen et al, , 1989Riehle et al, 1997;Grü n et al, 1999).…”

Section: Discussionmentioning

confidence: 99%

Single-trial estimation of neuronal firing rates: From single-neuron spike trains to population activity

Nawrot

Aertsen

Rotter

1999

Journal of Neuroscience Methods

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120

108

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We present a method to estimate the neuronal firing rate from single-trial spike trains. The method, based on convolution of the spike train with a fixed kernel function, is calibrated by means of simulated spike trains for a representative selection of realistic dynamic rate functions. We derive rules for the optimized use and performance of the kernel method, specifically with respect to an effective choice of the shape and width of the kernel functions. An application of our technique to the on-line, single-trial reconstruction of arm movement trajectories from multiple single-unit spike trains using dynamic population vectors illustrates a possible use of the proposed method.

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Spike Synchronization and Rate Modulation Differentially Involved in Motor Cortical Function

Cited by 851 publications

References 32 publications

Temporal Characteristics of the Predictive Synchronous Firing Modeled by Spike-Timing-Dependent Plasticity

Temporal Characteristics of the Predictive Synchronous Firing Modeled by Spike-Timing-Dependent Plasticity

Conditions for Propagating Synchronous Spiking and Asynchronous Firing Rates in a Cortical Network Model

Single-trial estimation of neuronal firing rates: From single-neuron spike trains to population activity

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