Prefrontal Cortex Neuron Activity During a Discriminative Conditioning Paradigm in Unanesthetized Rats

In the adult auditory system, loss of input resulting from peripheral deafferentation is well known to lead to plasticity in the central nervous system, manifested as reorganization of cortical maps and altered activity throughout the central auditory pathways. The auditory system also has strong afferent and efferent connections with cortico-limbic circuitry including the prefrontal cortex and the question arises whether this circuitry is also affected by loss of peripheral input. Recent studies in our laboratory showed that PFC activation can modulate activity of the auditory thalamus or medial geniculate nucleus (MGN) in normal hearing rats. In addition, we have shown in rats that cochlear trauma resulted in altered spontaneous burst firing in MGN. However, whether the PFC influence on MGN is changed after cochlear trauma is unknown. We investigated the effects of electrical stimulation of PFC on single neuron activity in the MGN in anaesthetized Wistar rats 2 weeks after acoustic trauma or sham surgery. Electrical stimulation of PFC showed a variety of effects in MGN neurons both in sham and acoustic trauma groups but inhibitory responses were significantly larger in the acoustic trauma animals. These results suggest an alteration in functional connectivity between PFC and MGN after cochlear trauma. This change may be a compensatory mechanism increasing sensory gating after the development of altered spontaneous activity in MGN, to prevent altered activity reaching the cortex and conscious perception.

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Functional inactivation of hypocretin 1 receptors in the medial prefrontal cortex affects the pyramidal neuron activity and gamma oscillations: An in vivo multiple-channel single-unit recording study

Neuroscience ◽

10.1016/j.neuroscience.2015.03.044 ◽

2015 ◽

Vol 297 ◽

pp. 1-10 ◽

Cited By ~ 4

Author(s):

C. He ◽

Q.-H. Chen ◽

J.-N. Ye ◽

C. Li ◽

L. Yang ◽

...

Keyword(s):

Prefrontal Cortex ◽

Single Unit ◽

Gamma Oscillations ◽

Neuron Activity ◽

Single Unit Recording ◽

Unit Recording ◽

Multiple Channel ◽

Functional Inactivation ◽

Hypocretin 1

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Representation of actions and outcomes in medial prefrontal cortex during delayed conditional decision-making: Population analyses of single neuron activity

Brain and Neuroscience Advances ◽

10.1177/2398212818773865 ◽

2018 ◽

Vol 2 ◽

pp. 239821281877386 ◽

Cited By ~ 2

Author(s):

Miranda J. Francoeur ◽

Robert G. Mair

Keyword(s):

Decision Making ◽

Prefrontal Cortex ◽

Medial Prefrontal Cortex ◽

Single Neuron ◽

Neuron Activity ◽

Related Activity ◽

Response Options ◽

Single Neuron Activity ◽

Temporal Organisation ◽

Matching To Position

Background: To respond adaptively in a dynamic environment, it is important for organisms to utilise information about recent events to decide between response options. Methods: To examine the role of medial prefrontal cortex in adaptive decision-making, we recorded single neuron activity in rats performing a dynamic delayed non-matching to position task. Results: We recorded activity from 1335 isolated neurons, 458 (34%) with criterion event-related activity, of which 431 (94%) exhibited 1 of 10 distinct excitatory response types: five at different times relative to delivery (or lack) of reinforcement following sample and choice responses and five correlated with movements or lever press actions that occurred multiple times in each trial. Normalised population averages revealed a precisely timed cascade of population responses representing the temporal organisation behavioural events that constitute delayed non-matching to position trials. Firing field analyses identified a subset of neurons with restricted spatial fields: responding to the conjunction of a behavioural event with a specific location. Anatomical analyses showed considerable overlap in the distribution of different response types in medial prefrontal cortex with a significant trend for dorsal areas to contain more neurons with action-related activity and ventral areas more responses related to action outcomes. Conclusion: These results indicate that medial prefrontal cortex contains discrete populations of neurons that represent the temporal organisation of actions and outcomes during delayed non-matching to position trials. They support the hypothesis that medial prefrontal cortex promotes flexible control of complex behaviours by action–outcome contingencies.

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Stable population coding for working memory coexists with heterogeneous neural dynamics in prefrontal cortex

Proceedings of the National Academy of Sciences ◽

10.1073/pnas.1619449114 ◽

2016 ◽

Vol 114 (2) ◽

pp. 394-399 ◽

Cited By ~ 128

Author(s):

John D. Murray ◽

Alberto Bernacchia ◽

Nicholas A. Roy ◽

Christos Constantinidis ◽

Ranulfo Romo ◽

...

Keyword(s):

Working Memory ◽

Prefrontal Cortex ◽

Neural Circuit ◽

Temporal Dynamics ◽

Population Level ◽

Population Coding ◽

Neural Dynamics ◽

Stable Population ◽

Neuron Activity ◽

Delayed Response

Working memory (WM) is a cognitive function for temporary maintenance and manipulation of information, which requires conversion of stimulus-driven signals into internal representations that are maintained across seconds-long mnemonic delays. Within primate prefrontal cortex (PFC), a critical node of the brain’s WM network, neurons show stimulus-selective persistent activity during WM, but many of them exhibit strong temporal dynamics and heterogeneity, raising the questions of whether, and how, neuronal populations in PFC maintain stable mnemonic representations of stimuli during WM. Here we show that despite complex and heterogeneous temporal dynamics in single-neuron activity, PFC activity is endowed with a population-level coding of the mnemonic stimulus that is stable and robust throughout WM maintenance. We applied population-level analyses to hundreds of recorded single neurons from lateral PFC of monkeys performing two seminal tasks that demand parametric WM: oculomotor delayed response and vibrotactile delayed discrimination. We found that the high-dimensional state space of PFC population activity contains a low-dimensional subspace in which stimulus representations are stable across time during the cue and delay epochs, enabling robust and generalizable decoding compared with time-optimized subspaces. To explore potential mechanisms, we applied these same population-level analyses to theoretical neural circuit models of WM activity. Three previously proposed models failed to capture the key population-level features observed empirically. We propose network connectivity properties, implemented in a linear network model, which can underlie these features. This work uncovers stable population-level WM representations in PFC, despite strong temporal neural dynamics, thereby providing insights into neural circuit mechanisms supporting WM.

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Prefrontal Task-Related Activity Representing Visual Cue Location or Saccade Direction in Spatial Working Memory Tasks

Journal of Neurophysiology ◽

10.1152/jn.00249.2001 ◽

2002 ◽

Vol 87 (1) ◽

pp. 567-588 ◽

Cited By ~ 105

Author(s):

Kazuyoshi Takeda ◽

Shintaro Funahashi

Keyword(s):

Working Memory ◽

Prefrontal Cortex ◽

Spatial Working Memory ◽

Delay Period ◽

Neuron Activity ◽

Delayed Response ◽

Related Activity ◽

Visual Cue ◽

Response Period ◽

Dorsolateral Prefrontal

To examine what kind of information task-related activity encodes during spatial working memory processes, we analyzed single-neuron activity in the prefrontal cortex while two monkeys performed two different oculomotor delayed-response (ODR) tasks. In the standard ODR task, monkeys were required to make a saccade to the cue location after a 3-s delay, whereas in the rotatory ODR (R-ODR) task, they were required to make a saccade 90° clockwise from the cue location after the 3-s delay. By comparing the same task-related activities in these two tasks, we could determine whether such activities encoded the location of the visual cue or the direction of the saccade. One hundred twenty one neurons exhibited task-related activity in relation to at least one task event in both tasks. Among them, 41 neurons exhibited directional cue-period activity, most of which encoded the location of the visual cue. Among 56 neurons with directional delay-period activity, 86% encoded the location of the visual cue, whereas 13% encoded the direction of the saccade. Among 57 neurons with directional response-period activity, 58% encoded the direction of the saccade, whereas 35% encoded the location of the visual cue. Most neurons whose response-period activity encoded the location of the visual cue also exhibited directional delay-period activity that encoded the location of the visual cue as well. The best directions of these two activities were identical, and most of these response-period activities were postsaccadic. Therefore this postsaccadic activity can be considered a signal to terminate unnecessary delay-period activity. Population histograms encoding the location of the visual cue showed tonic sustained activation during the delay period. However, population histograms encoding the direction of the saccade showed a gradual increase in activation during the delay period. These results indicate that the transformation from visual input to motor output occurs in the dorsolateral prefrontal cortex. The analysis using population histograms suggests that this transformation occurs gradually during the delay period.

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Theta oscillations synchronize human medial prefrontal cortex and amygdala during fear learning

Science Advances ◽

10.1126/sciadv.abf4198 ◽

2021 ◽

Vol 7 (34) ◽

pp. eabf4198

Author(s):

Si Chen ◽

Zheng Tan ◽

Wenran Xia ◽

Carlos Alexandre Gomes ◽

Xilei Zhang ◽

...

Keyword(s):

Prefrontal Cortex ◽

Medial Prefrontal Cortex ◽

Animal Studies ◽

Theta Oscillations ◽

Fear Learning ◽

General Mechanism ◽

Conditioning Paradigm ◽

Amygdala Activity ◽

Intracranial Electroencephalography ◽

Patients With Epilepsy

Numerous animal studies have demonstrated that fear acquisition and expression rely on the coordinated activity of medial prefrontal cortex (mPFC) and amygdala and that theta oscillations support interregional communication within the fear network. However, it remains unclear whether these results can be generalized to fear learning in humans. We addressed this question using intracranial electroencephalography recordings in 13 patients with epilepsy during a fear conditioning paradigm. We observed increased power and inter-regional synchronization of amygdala and mPFC in theta (4 to 8 hertz) oscillations for conditioned stimulus (CS+) versus CS−. Analysis of information flow revealed that the dorsal mPFC (dmPFC) led amygdala activity in theta oscillations. Last, a computational model showed that trial-by-trial changes in amygdala theta oscillations predicted the model-based associability (i.e., learning rate). This study provides compelling evidence that theta oscillations within and between amygdala, ventral mPFC, and dmPFC constitute a general mechanism of fear learning across species.

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Comparison of abstract decision encoding in the monkey prefrontal cortex, the presupplementary, and cingulate motor areas

Journal of Neurophysiology ◽

10.1152/jn.00686.2012 ◽

2013 ◽

Vol 110 (1) ◽

pp. 19-32 ◽

Cited By ~ 10

Author(s):

Katharina Merten ◽

Andreas Nieder

Keyword(s):

Prefrontal Cortex ◽

Cognitive Processing ◽

Planning Process ◽

Motor Planning ◽

Motor Preparation ◽

Neuron Activity ◽

Critical Element ◽

Cingulate Motor Area ◽

Monkey Prefrontal Cortex

Deciding between alternatives is a critical element of flexible behavior. Perceptual decisions have been studied extensively in an action-based framework. Recently, we have shown that abstract perceptual decisions are encoded in prefrontal cortex (PFC) neurons ( Merten and Nieder 2012 ). However, the role of other frontal cortex areas remained elusive. Here, we trained monkeys to perform a rule-based visual detection task that disentangled abstract perceptual decisions from motor preparation. We recorded the single-neuron activity in the presupplementary (preSMA) and the rostral part of the cingulate motor area (CMAr) and compared it to the results previously found in the PFC. Neurons in both areas traditionally identified with motor planning process the abstract decision independently of any motor preparatory activity by similar mechanisms as the PFC. A larger proportion of decision neurons and a higher strength of decision encoding was found in the preSMA than in the PFC. Neurons in both areas reliably predicted the monkeys' decisions. The fraction of CMAr decision neurons and their strength of the decision encoding were comparable to the PFC. Our findings highlight the role of both preSMA and CMAr in abstract cognitive processing and emphasize that both frontal areas encode decisions prior to the preparation of a motor output.

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Visuospatial coding in primate prefrontal neurons revealed by oculomotor paradigms

Journal of Neurophysiology ◽

10.1152/jn.1990.63.4.814 ◽

1990 ◽

Vol 63 (4) ◽

pp. 814-831 ◽

Cited By ~ 255

Author(s):

S. Funahashi ◽

C. J. Bruce ◽

P. S. Goldman-Rakic

Keyword(s):

Prefrontal Cortex ◽

Visual Field ◽

Visual Cues ◽

Neuron Activity ◽

Delayed Response ◽

Visual Response ◽

Visual Responses ◽

Directional Tuning ◽

Vertical Meridian ◽

Visual Probe

1. Visual responses and their relationship to delay-period activity were studied by recording single neuron activity from the prefrontal cortex of rhesus monkeys while they performed an oculomotor delayed-response (ODR) and a visual probe (VP) task. In the ODR task, the monkey was required to maintain fixation of a central spot of light throughout the cue (0.5 s) and delay (3 s) periods and then make a saccadic eye movement to one of four or eight locations where the visual cue had been presented. In the VP task, the same visual stimuli that were used in the ODR task were presented for 0.5 s, but no response was required. The VP task was thus employed to test the passive visual response and, by comparison with cue-elicited activity in the ODR task, to examine the degree of behavioral enhancement present in prefrontal visual activity. 2. Among 434 neurons recorded from the prefrontal cortex within and surrounding the principal sulcus (PS), 261 had task-related activity during at least one phase of the ODR task, and 74 of these had phasic visual responses to the onset of the visual cues with a median latency of 116 ms. The visual responses of 69 neurons were excitatory, and 5 neurons were inhibited. Five of the neurons with excitatory visual responses also responded transiently after the offset of the cue. 3. Visual responses were classified as directional for 71 PS neurons (96%) in that excitatory or inhibitory responses occurred only for location of cues in a restricted portion of the visual field. Only 3 PS neurons were omnidirectional, i.e., responded equivalently to cues in all locations tested. 4. The best direction and tuning specificity of all PS neurons with directional visual responses were estimated from parameters yielding the best fit to a Gaussian-shaped tuning function. The best direction for the majority (71%) of neurons was toward the visual field contralateral to the hemisphere where the neuron was located. The remaining neurons had their best directions in the ipsilateral field (18%) or along the vertical meridian (11%). 5. The specificity of directional tuning for PS visual responses was quite variable, ranging from neurons that responded only to one of the eight cue locations to neurons that responded to all eight, but in a clearly graded fashion. The standard deviation parameter of the Gaussian curve indexed the breadth of directional tuning of each neuron; its median value was 37 degrees.(ABSTRACT TRUNCATED AT 400 WORDS)

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