Complementary Contributions of Spike Timing and Spike Rate to Perceptual Decisions in Rat S1 and S2 Cortex

Zuo, Yuhua; Safaai, Houman; Notaro, Giuseppe; Mazzoni, Annalisa; Panzeri, Stefano; Diamond, Mathew E.

doi:10.1016/j.cub.2014.11.065

Cited by 148 publications

(185 citation statements)

References 38 publications

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“…Integration is also implicated in discrimination of surface texture (roughness), in which surface whisking generates temporally dense sequences of stick-slip whisker micromotions, whose mean statistics, including mean whisker speed, correlate with roughness [3,4,21,30–33]. S1 neurons spike phasically to stick/slip events and other features such as dynamic changes in whisker bend [3,21,34], and behavioral judgments of surface roughness correlate with mean firing rate and rate of synchronous spiking across S1 neurons [21,35,36]. Thus, roughness discrimination likely involves temporal integration of stick/slip events and S1 spike trains.…”

Section: Discussionmentioning

confidence: 99%

Short Time-Scale Sensory Coding in S1 during Discrimination of Whisker Vibrotactile Sequences

et al. 2016

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Rodent whisker input consists of dense microvibration sequences that are often temporally integrated for perceptual discrimination. Whether primary somatosensory cortex (S1) participates in temporal integration is unknown. We trained rats to discriminate whisker impulse sequences that varied in single-impulse kinematics (5–20-ms time scale) and mean speed (150-ms time scale). Rats appeared to use the integrated feature, mean speed, to guide discrimination in this task, consistent with similar prior studies. Despite this, 52% of S1 units, including 73% of units in L4 and L2/3, encoded sequences at fast time scales (≤20 ms, mostly 5–10 ms), accurately reflecting single impulse kinematics. 17% of units, mostly in L5, showed weaker impulse responses and a slow firing rate increase during sequences. However, these units did not effectively integrate whisker impulses, but instead combined weak impulse responses with a distinct, slow signal correlated to behavioral choice. A neural decoder could identify sequences from fast unit spike trains and behavioral choice from slow units. Thus, S1 encoded fast time scale whisker input without substantial temporal integration across whisker impulses.

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Section: Discussionmentioning

confidence: 99%

Short Time-Scale Sensory Coding in S1 during Discrimination of Whisker Vibrotactile Sequences

et al. 2016

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“…Anatomy 19,20 and physiology in anesthetized/narcotized rodents 21–23 suggest that mouse S2 is a higher, or more integrative, cortical area compared with S1. However, responses of rodent S2 neurons during tactile behavior are nearly entirely unexplored (but see: 24,25 ). We thus began by mapping responses to stimulation of a single whisker across whisker representation areas of S1 and S2, in separate mice, as they performed the detection task.…”

Section: Resultsmentioning

confidence: 99%

“…Neurons in both S1 and S2 propagated stimulus- and choice-related activity to the other area. However, neurons in each area also showed key differences in their response properties (see also: 24,25 ). S2 activity was more associated with perceptual outcome compared with S1, whereas S1 activity better encoded the stimulus.…”

Section: Discussionmentioning

confidence: 99%

Sensory and decision-related activity propagate in a cortical feedback loop during touch perception

et al. 2016

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The brain transforms physical sensory stimuli into meaningful perceptions. In animals making choices about sensory stimuli, neuronal activity in successive cortical stages reflects a progression from sensation to decision. Feedforward and feedback pathways connecting cortical areas are critical for this transformation. However, the computational roles of these pathways are poorly understood because pathway-specific activity has rarely been monitored during a perceptual task. Using cellular-resolution, pathway-specific imaging, we measured neuronal activity across primary (S1) and secondary (S2) somatosensory cortices of mice performing a tactile detection task. S1 encoded the stimulus better than S2, while S2 activity more strongly reflected perceptual choice. S1 neurons projecting to S2 fed forward activity that predicted choice. Activity encoding touch and choice propagated in an S1–S2 loop along feedforward and feedback axons. Our results suggest that sensory inputs converge into a perceptual outcome as feedforward computations are reinforced in a feedback loop.

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“…Information transmission in the brain presumably does not rely exclusively on a summed population activity, but rather is also mediated by the precise spike times of individual cells (Strong et al, 1998;Zuo et al, 2015). Measuring and modeling the singleneuron response to time-dependent stimuli thus remains a crucial task in understanding the neural code (Rieke et al, 1996).…”

Section: Introductionmentioning

confidence: 99%

Noisy Juxtacellular StimulationIn VivoLeads to Reliable Spiking and Reveals High-Frequency Coding in Single Neurons

et al. 2016

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Single cells in the motor and somatosensory cortex of rats were stimulated in vivo with broadband fluctuating currents applied juxtacellularly. Unlike the DC current steps used previously, fluctuating stimulation currents reliably evoked spike trains with precise timing of individual spikes. Fluctuating currents resulted in strong cellular responses at stimulation frequencies beyond the inverse membrane time constant and the mean firing rate of the neuron. Neuronal firing was associated with high rates of information transmission, even for the high-frequency components of the stimulus. Such response characteristics were also revealed in additional experiments with sinusoidal juxtacellular stimulation. For selected cells, we could reproduce these statistics with compartmental models of varying complexity. We also developed a method to generate Gaussian stimuli that evoke spike trains with prescribed spike times (under the constraint of a certain rate and coefficient of variation) and exemplify its ability to achieve precise and reliable spiking in cortical neurons in vivo. Our results demonstrate a novel method for precise control of spike timing by juxtacellular stimulation, confirm and extend earlier conclusions from ex vivo work about the capacity of cortical neurons to generate precise discharges, and contribute to the understanding of the biophysics of information transfer of single neurons in vivo at high frequencies.

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Complementary Contributions of Spike Timing and Spike Rate to Perceptual Decisions in Rat S1 and S2 Cortex

Cited by 148 publications

References 38 publications

Short Time-Scale Sensory Coding in S1 during Discrimination of Whisker Vibrotactile Sequences

Short Time-Scale Sensory Coding in S1 during Discrimination of Whisker Vibrotactile Sequences

Sensory and decision-related activity propagate in a cortical feedback loop during touch perception

Noisy Juxtacellular StimulationIn VivoLeads to Reliable Spiking and Reveals High-Frequency Coding in Single Neurons

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