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Adaptive, behaviorally gated, persistent encoding of task-relevant auditory information in ferret frontal cortex

Adaptive, behaviorally gated, persistent encoding of task-relevant auditory information in ferret frontal cortex . introductions. Studies of prefrontal cortex (PFC) have provided considerable evidence for it being involved in high-level executive functions.

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Adaptive, behaviorally gated, persistent encoding of task-relevant auditory information in ferret frontal cortex

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  1. Adaptive, behaviorally gated, persistent encoding of task-relevant auditory information in ferret frontal cortex

  2. introductions • Studies of prefrontal cortex (PFC) have provided considerable evidence for it being involved in high-level executive functions. • Top-down signals from frontal cortex are thought to be important in cognitive control of sensory processing • A fundamental component of these functions is the cognitive control of the flow of sensory inputs through cortex via top-down feedback from PFC.

  3. introductions • If frontal cortex is a source of top-down command signals that modulate sensory representations for optimal processing of task- relevant information, one would predict that this modulation would be contingent on behavioral state and task-dependent stimulus meaning. One would also predict a strong correspondence between modulation of evoked sensory responses in frontal cortex and in task-relevant sensory areas. • To explore and test this hypothesis, they used the ferret to study frontal cortex (including areas in the orbital gyrus (OBG) and anterior sigmoid gyrus (ASG) ) control of auditory behavior.

  4. introductions • They recorded the activity of single neurons and the local field potential (LFP) in two cortical areas of ferret frontal cortex (ASG and the dorsal aspect of OBG) during auditory discrimination behaviors (tone detection and two-tone discrimination. • They compared activity in ferret frontal cortex and primary auditory cortex (A1) during auditory and visual tasks requiring discrimination between classes of reference and target stimuli.

  5. Methods and Results: recording locations

  6. Methods and Results: the basic structure of all tasks • Behavior: ferrets learned by conditioned avoidance to lick water from a spout during the presentation of a class of reference stimuli and to cease licking after the presentation of the class of target stimuli to avoid a mild shock. • Sensory (Auditory or visual) stimuli:

  7. Methods and Results: Frontal cortex responses are gated by behavior

  8. Methods and Results: suppression and excitation

  9. Methods and Results: Frontal cortex responses encode behavioral meaning of stimuli

  10. Methods and Results: Persistence and extinction of post-behavioral responses

  11. Methods and Results:Category-specific changes in LFP across frontal cortex and A1

  12. Methods and Results: Frontal cortex responses to auditory and visual target stimuli

  13. Discussion • Behavioral gating of frontal cortex responses :The majority of responses in frontal cortex were behaviorally gated and highly selective for target stimuli, with roughly equal numbers of neurons showing enhanced or suppressed modulation during behavior. • Adaptive and selective representation of target stimuli : The ability to change behavioral and neural responses to identical sensory stimuli, depending on current task and context, is an essential component of flexible, goal-directed behavior. Neurons in frontal cortex are likely to contribute to this adaptive ability because of their extraordinary flexibility, responding differently to identical stimuli depending on the task requirements and behavioral contexts. Their results are consistent with these findings, as demonstrated by the rapid, adaptive change in coding between tone-detection and tone-discrimination tasks.

  14. Discussion • Array of response latencies and event timing in frontal cortex :The time at which cortical neurons respond to sensory stimuli can provide insight into their functional role and the level that the neurons occupy in the bi-directional sensory-to–decision-making hierarchy. In frontal cortex neurons, target modulation latencies ranged from early to late (from 20 ms to over 1,500 ms). • The lasting imprint of attention in A1 and frontal cortex :Frontal cortex neurons exhibited adaptive responses that were markedly similar in their rapid onset with behavior and variable persistence following behavior to changes in spectro-temporal receptive field shape for salient acoustic features in A1. As in A1, frontal cortex recordings post-behavior revealed responses that could persist for minutes to hours following task performance. They suggest that these persistent responses, triggered by attention, correspond to changes in stimulus meaning that last long after the behavioral epoch.

  15. Discussion • LFP gating and feature-selective changes in inter-areal coherence : Their simultaneous measurements of LFP in A1 and frontal cortex revealed coherence that changed substantially depending on behavioral state and the behavioral meaning of incoming stimuli. The clear decrease in coherence was selective for A1 sites that responded to the target frequency (near cells), whereas only a small change was observed when target frequency was distant from the best frequency of the A1 site (far cells).

  16. Thanks for your attention!

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