Routing information flow by separate neural synchrony frequencies allows for “functionally labeled lines” in higher primate cortex

Khamechian, Mohammad Bagher; Kozyrev, Vladislav; Treue, Stefan; Esghaei, Moein; Daliri, Mohammad Reza

doi:10.1073/pnas.1819827116

Cited by 31 publications

(38 citation statements)

References 100 publications

(141 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Human psychophysical experiments also reinforce the point that gating functions of the dorsal stream prioritise spatial locations rather than specific features (27). The different frequencies for the two functions may also be functionally fortuitous, consistent with recent evidence that the brain may use different synchronising frequencies for different functions (20).…”

Section: One Sentence Summarysupporting

confidence: 80%

“…As can be seen in these three example cases and also when analysed across all those recording sessions where there was both significant LFP coherence and a multiunit response (MU) to the first grating, there was a significant latency difference between the spike response maxima and the coherence maxima in both areas (LIP: N=14 recording sites, p<0.001; MT: N=15, p< 0.001, Wilcoxon Signed Rank test). In MT, the peak spike response preceded the coherence maximum by 279 ms and in LIP by 341 ms. A recent study done in area MT also shows that synchrony seen at certain high gamma frequencies (180-220 Hz) represents sensory signals rather than a reflection of spike leakage (20), adding further credence to the importance of high gamma frequencies in information processing.…”

Section: One Sentence Summarymentioning

confidence: 88%

See 1 more Smart Citation

Dynamics of coherent activity between cortical areas defines a two-stage process of selective attention

Levichkina

Kermani

Saalmann

et al. 2020

Preprint

View full text Add to dashboard Cite

show abstract

Section: One Sentence Summarysupporting

confidence: 80%

Section: One Sentence Summarymentioning

confidence: 88%

Dynamics of coherent activity between cortical areas defines a two-stage process of selective attention

Levichkina

Kermani

Saalmann

et al. 2020

Preprint

View full text Add to dashboard Cite

show abstract

“…These findings are consistent with a communication-through-coherence schema where upstream senders are more coherent with downstream readers when they successfully compete for representation (Bosman et al, 2012;Fries, 2015;. Yet it has remained unclear how such a scheme may operate when multiple items must be multiplexed and transmitted in the same recurrent network (Akam and Kullmann, 2014;Khamechian et al, 2019;Kopell et al, 2011;Palminteri et al, 2015;Siegel et al, 2009). Computationally, the multiplexing and the efficient transmission of information can operate in tandem when the temporal organization of activity is exploited at the sending and receiving site (Buzsáki, 2010;Hahn et al, 2019;Kumar et al, 2010;Luczak et al, 2015).…”

Section: Multiplexing Of Information Through Phase-of-firing Encodingsupporting

confidence: 71%

Phase of Firing Coding of Learning Variables across Prefrontal Cortex, Anterior Cingulate Cortex and Striatum during Feature Learning

Voloh

Oemisch

Womelsdorf

2019

Preprint

View full text Add to dashboard Cite

KeywordsLearning; beta frequency oscillation; neuronal synchronization; prediction error phase code; anterior cingulate cortex; striatum; lateral prefrontal cortex; reward prediction error, reversal learning Highlights • Lateral prefrontal cortex, anterior cingulate cortex and striatum show phase-of-firing encoding for outcome, outcome history and reward prediction errors.• Neurons with phase-of-firing code synchronize long-range at 10-25 Hz.• Spike phases encoding reward prediction errors deviate from preferred synchronization phases.• Anterior cingulate cortex neurons show strongest long-range effects. AbstractThe prefrontal cortex and striatum form a recurrent network whose spiking activity encodes multiple types of learning-relevant information. This spike-encoded information is evident in average firing rates, but finer temporal coding might allow multiplexing and enhanced readout across the connected the network. We tested this hypothesis in the fronto-striatal network of nonhuman primates during reversal learning of feature values. We found that neurons encoding current choice outcomes, outcome prediction errors, and outcome history in their firing rates also carried significant information in their phase-of-firing at a 10-25 Hz beta frequency at which they synchronized across lateral prefrontal cortex, anterior cingulate cortex and striatum. The phase-of-firing code exceeded information that could be obtained from firing rates alone, was strong for inter-areal connections, and multiplexed Combined Manuscript File 2 information at three different phases of the beta cycle that were offset from the preferred spiking phase of neurons. Taken together, these findings document the multiplexing of three different types of information in the phase-of-firing at an interareally shared beta oscillation frequency during goal-directed behavior.

show abstract

“…increases with attention in a behaviorally relevant manner 16,27,30 . Moreover, recent investigations document a prominent role of low frequency oscillations, especially in the alpha/theta band, in attentional processing and shaping large-scale task-related functional networks of the brain [31][32][33] .…”

mentioning

confidence: 99%

“…Attentional influences on neural responses in sensory cortex have been extensively documented; effects which reflect a multitude of aspects of cortical information processing 1-4 . Covertly directing attention towards the receptive field of a neuron in visual cortex enhances the neural responses even in the absence of visual stimulation 5,6 , alters the shape and profile of receptive fields 7-9 , modulates the variability and temporal structure of the neuron's firing patterns 10,11 , modulates inter-neuronal correlations to increase neural discriminability 12,13 and synchronizes neighboring neurons, presumably to better propagate information to downstream areas [14][15][16] .Attention has been suggested to exploit oscillatory neural activities, as well as oscillatory components of local field potentials (LFP), to enhance the efficacy of cortical processing 17-23 . LFPs represent synaptic activities of local cortical neuronal populations 24 .…”

mentioning

confidence: 99%

Attention strengthens across-trial pre-stimulus phase coherence in visual cortex, enhancing stimulus processing

Zareian

Maboudi

Daliri

et al. 2020

Sci Rep

Self Cite

View full text Add to dashboard Cite

Attention selectively routes the most behaviorally relevant information from the stream of sensory inputs through the hierarchy of cortical areas. previous studies have shown that visual attention depends on the phase of oscillatory brain activities. these studies mainly focused on the stimulus presentation period, rather than the pre-stimulus period. Here, we hypothesize that selective attention controls the phase of oscillatory neural activities to efficiently process relevant information. We document an attentional modulation of pre-stimulus inter-trial phase coherence (a measure of deviation between instantaneous phases of trials) of low frequency local field potentials (LFP) in visual area Mt of macaque monkeys. our data reveal that phase coherence increases following a spatial cue deploying attention towards the receptive field of the recorded neural population. We further show that the attentional enhancement of phase coherence is positively correlated with the modulation of the stimulus-induced firing rate, and importantly, a higher phase coherence is associated with a faster behavioral response. these results suggest a functional utilization of intrinsic neural oscillatory activities for an enhanced processing of upcoming stimuli.One of the most important cognitive functions of the mammalian brain is selective attention. Attention selectively routes the most behaviorally relevant information from the stream of sensory inputs through the hierarchy of cortical areas. This allows the brain to make the most efficient use of its limited neural resources and to create appropriate behavioral responses quickly 1 . Attentional influences on neural responses in sensory cortex have been extensively documented; effects which reflect a multitude of aspects of cortical information processing 1-4 . Covertly directing attention towards the receptive field of a neuron in visual cortex enhances the neural responses even in the absence of visual stimulation 5,6 , alters the shape and profile of receptive fields 7-9 , modulates the variability and temporal structure of the neuron's firing patterns 10,11 , modulates inter-neuronal correlations to increase neural discriminability 12,13 and synchronizes neighboring neurons, presumably to better propagate information to downstream areas [14][15][16] .Attention has been suggested to exploit oscillatory neural activities, as well as oscillatory components of local field potentials (LFP), to enhance the efficacy of cortical processing 17-23 . LFPs represent synaptic activities of local cortical neuronal populations 24 . Their oscillations are tightly linked to attention in both low and high frequencies 18,[25][26][27][28][29] . Previous studies have shown that synchronization in the gamma as well as high gamma band

show abstract

Routing information flow by separate neural synchrony frequencies allows for “functionally labeled lines” in higher primate cortex

Cited by 31 publications

References 100 publications

Dynamics of coherent activity between cortical areas defines a two-stage process of selective attention

Dynamics of coherent activity between cortical areas defines a two-stage process of selective attention

Phase of Firing Coding of Learning Variables across Prefrontal Cortex, Anterior Cingulate Cortex and Striatum during Feature Learning

Attention strengthens across-trial pre-stimulus phase coherence in visual cortex, enhancing stimulus processing

Contact Info

Product

Resources

About