Plasticity of Persistent Activity and Its Constraints.

Sihai Li,Christos Constantinidis,Xue-Lian Qi,Xin Zhou

doi:10.3389/fncir.2020.00015

Sihai Li, Christos Constantinidis + Show 2 more

Open Access

https://doi.org/10.3389/fncir.2020.00015

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Abstract

Stimulus information is maintained in working memory by action potentials that persist after the stimulus is no longer physically present. The prefrontal cortex is a critical brain area that maintains such persistent activity due to an intrinsic network with unique synaptic connectivity, NMDA receptors, and interneuron types. Persistent activity can be highly plastic depending on task demands but it also appears in naïve subjects, not trained or required to perform a task at all. Here, we review what aspects of persistent activity remain constant and what factors can modify it, focusing primarily on neurophysiological results from non-human primate studies. Changes in persistent activity are constrained by anatomical location, with more ventral and more anterior prefrontal areas exhibiting the greatest capacity for plasticity, as opposed to posterior and dorsal areas, which change relatively little with training. Learning to perform a cognitive task for the first time, further practicing the task, and switching between learned tasks can modify persistent activity. The ability of the prefrontal cortex to generate persistent activity also depends on age, with changes noted between adolescence, adulthood, and old age. Mean firing rates, variability and correlation of persistent discharges, but also time-varying firing rate dynamics are altered by these factors. Plastic changes in the strength of intrinsic network connections can be revealed by the analysis of synchronous spiking between neurons. These results are essential for understanding how the prefrontal cortex mediates working memory and intelligent behavior.

Highlights

Working memory, the ability to maintain and manipulate information in mind over seconds, is one of the key components of higher cognitive functions (Baddeley, 2012)
We focus on the lateral prefrontal cortex, the brain region most intricately implicated in this function, in non-human primates (Constantinidis and Procyk, 2004)
This review summarized the current state of knowledge on the generation and plasticity of persistent activity during working memory

Summary

Introduction

The ability to maintain and manipulate information in mind over seconds, is one of the key components of higher cognitive functions (Baddeley, 2012). Neurophysiological studies identified neurons in the lateral prefrontal cortex that generate persistent activity during working memory tasks (Fuster and Alexander, 1971; Kubota and Niki, 1971). The activity of individual prefrontal neurons was shown to be sensitive to the identity and location of remembered stimuli (Fuster and Alexander, 1971; Funahashi et al, 1989; Constantinidis et al, 2001b), as well as task variables, quantities, and categorical judgments (Freedman et al, 2001; Crowe et al, 2013; Blackman et al, 2016). Working memory is not the only cognitive domain that persistent neural activity seems to predict (Constantinidis and Luna, 2019). Response preparation is a critical parameter of inhibitory control (DeSouza et al, 2003; Ordaz et al, 2010) and baseline activity may be tied to working memory, encoding advance preparation for the upcoming requirement to resist the stimulus appearance

Objectives

Conclusion