Ultrafast Population Encoding by Cortical Neurons

Tchumatchenko, Tatjana; Malyshev, Aleksey; Wolf, Fred; Volgushev, Maxim

doi:10.1523/jneurosci.2182-11.2011

Cited by 97 publications

(161 citation statements)

References 37 publications

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“…Neurons of both types can phase-lock their firing to high frequencies: layer 2/3 pyramids up to ~300 to 400 Hz, and layer 5 pyramids to even higher frequencies of up to ~600 to 700 Hz. These results agree with a number of reports on experimental measurements of frequency response functions in pyramidal neurons from different areas of the neocortex (Boucsein and others 2009; Broicher and others 2012; Higgs and Spain 2009; 2011; Ilin and others 2013; Kondgen and others 2008; Tchumatchenko and others 2011). In a linear system, characteristics of the response in time domain and frequency domain are related.…”

Section: Ultrafast Responses Of Cortical Neurons: Experimental Evidencesupporting

confidence: 92%

“…Detection time can be also decreased by increasing the signal amplitude, for example by increasing input synchrony. These dependences, initially predicted theoretically (Brunel and others 2001; Fourcaud-Trocme and Brunel 2005; Fourcaud-Trocme and others 2003; Huang and others 2012; Naundorf and others 2005; Wei and Wolf 2011), have now been supported by experimental evidence from neocortical neurons (Boucsein and others 2009; Higgs and Spain 2011; Ilin and others 2013; Ilin and others 2014; Kondgen and others 2008; Tchumatchenko and others 2011). …”

Section: Cellular and Network Mechanisms That Affect The Speed Of Neusupporting

confidence: 54%

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Cortical Specializations Underlying Fast Computations

Volgushev

2015

Neuroscientist

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The time course of behaviorally relevant environmental events sets temporal constraints on neuronal processing. How does the mammalian brain make use of the increasingly complex networks of the neocortex, while making decisions and executing behavioral reactions within a reasonable time? The key parameter determining the speed of computations in neuronal networks is a time interval that neuronal ensembles need to process changes at their input and communicate results of this processing to downstream neurons. Theoretical analysis identified basic requirements for fast processing: use of neuronal populations for encoding, background activity, and fast onset dynamics of action potentials in neurons. Experimental evidence shows that populations of neocortical neurons fulfil these requirements. Indeed, they can change firing rate in response to input perturbations very quickly, within 1 to 3 ms, and encode high-frequency components of the input by phase-locking their spiking to frequencies up to 300 to 1000 Hz. This implies that time unit of computations by cortical ensembles is only few, 1 to 3 ms, which is considerably faster than the membrane time constant of individual neurons. The ability of cortical neuronal ensembles to communicate on a millisecond time scale allows for complex, multiple-step processing and precise coordination of neuronal activity in parallel processing streams, while keeping the speed of behavioral reactions within environmentally set temporal constraints.

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Section: Ultrafast Responses Of Cortical Neurons: Experimental Evidencesupporting

confidence: 92%

Section: Cellular and Network Mechanisms That Affect The Speed Of Neusupporting

confidence: 54%

Cortical Specializations Underlying Fast Computations

Volgushev

2015

Neuroscientist

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“…By contrast, estimating the overall activity of a large population of neurons requires much less time, since one can simply count the number of spiking neurons firing within a short interval (essentially replacing temporal integration with spatial integration). This might explain how large populations of neurons can respond to a change in input current extremely fast, within the first few milliseconds of stimulation—much faster than individual membrane voltage dynamics34. Thus, the organization of neural activity into discrete collective patterns might conceivably represent a sacrifice of potential representativity in exchange for much faster decoding by downstream neurons—trading discriminative power for temporal precision.…”

Section: Discussionmentioning

confidence: 99%

Spontaneous emergence of fast attractor dynamics in a model of developing primary visual cortex

2016

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Recent evidence suggests that neurons in primary sensory cortex arrange into competitive groups, representing stimuli by their joint activity rather than as independent feature analysers. A possible explanation for these results is that sensory cortex implements attractor dynamics, although this proposal remains controversial. Here we report that fast attractor dynamics emerge naturally in a computational model of a patch of primary visual cortex endowed with realistic plasticity (at both feedforward and lateral synapses) and mutual inhibition. When exposed to natural images (but not random pixels), the model spontaneously arranges into competitive groups of reciprocally connected, similarly tuned neurons, while developing realistic, orientation-selective receptive fields. Importantly, the same groups are observed in both stimulus-evoked and spontaneous (stimulus-absent) activity. The resulting network is inhibition-stabilized and exhibits fast, non-persistent attractor dynamics. Our results suggest that realistic plasticity, mutual inhibition and natural stimuli are jointly necessary and sufficient to generate attractor dynamics in primary sensory cortex.

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“…Because P-unit action potentials lock onto the EOD (Hagiwara and Morita 1963), their membrane time constant is likely to be shorter than a single EOD period (ϳ1 ms) and thus potentially explains the ability of the P-units to quickly follow such a mean-coded signal. Cortical neurons also have been shown to rapidly follow mean-coded signals (Boucsein et al 2009;Tchumatchenko et al 2011). A variancecoded transmission that was suggested for rapid signal transmission (Silberberg et al 2004) is therefore not required.…”

Section: Discussionmentioning

confidence: 99%