Between persistently active and activity‐silent frameworks: novel vistas on the cellular basis of working memory

Kamiński, Jan; Rutishauser, Ueli

doi:10.1111/nyas.14213

Cited by 73 publications

(74 citation statements)

References 70 publications

(191 reference statements)

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“…Finally, we consider the proposal that functionally active states are supported by elevated neural activity, whereas functionally latent states correspond to activity-silent mnemonic mechanisms. This distinction has been suggested by a number of authors (e.g., Kamiński & Rutishauser, 2019;LaRocque et al, 2013LaRocque et al, , 2015Lewis-Peacock et al, 2012;Manohar et al, 2019;Olivers et al, 2011;Stokes, 2015). In the framework developed here, this division of labour is only helpful if it confers differential functional properties on active and latent WMs.…”

Section: Separation By Neurophysiological Mechanismmentioning

confidence: 91%

Theoretical distinction between functional states in working memory and their corresponding neural states

2020

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Working memory (WM) is important for guiding behaviour, but not always for the next possible action. Here we define a WM item that is currently relevant for guiding behaviour as the functionally "active" item; whereas items maintained in WM, but not immediately relevant to behaviour, are defined as functionally "latent". Traditional neurophysiological theories of WM proposed that content is maintained via persistent neural activity (e.g., stable attractors); however, more recent theories have highlighted the potential role for "activity-silent" mechanisms (e.g., short-term synaptic plasticity). Given these somewhat parallel dichotomies, functionally active and latent cognitive states of WM have been associated with storage based on persistent-activity and activity-silent neural mechanisms, respectively. However, in this article we caution against a one-to-one correspondence between functional and activity states. We argue that the principal theoretical requirement for active and latent WM is that the corresponding neural states play qualitatively different functional roles. We consider a number of candidate solutions, and conclude that the neurophysiological mechanisms for functionally active and latent WM items are theoretically independent of the distinction between persistent activity-based and activity-silent forms of WM storage.

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Section: Separation By Neurophysiological Mechanismmentioning

confidence: 91%

Theoretical distinction between functional states in working memory and their corresponding neural states

2020

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“…Updating and maintaining working memory content requires collaboration between multiple areas in the brain. Core neural structures are located in the posterior parietal cortex and prefrontal cortex, while the role of the MTL is unclear (for reviews see (5, 6)). The posterior parietal cortex supports elementary functions that are necessary for multiple object maintenance.…”

Section: Introductionmentioning

confidence: 99%

“…Electrophysiology and neuroimaging evidence specifically links MTL activity to maintenance in working memory. A recent review on single neuron recordings suggested direct involvement of MTL neural firing patterns in working memory (6). Patterns of neural activity were consistent to specific predictions from Cowan’s activated long-term memory model of working memory.…”

Section: Introductionmentioning

confidence: 99%

Neuronal firing in the medial temporal lobe reflects human working memory workload, performance and capacity

Boran

Hilfiker

Stieglitz

et al. 2020

Preprint

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Significance 15Humans are highly limited in processing multiple objects over a short period of time. 16The capacity to retain multiple objects in working memory is typically associated with 17 frontal and parietal lobe functioning, even though medial temporal lobe (MTL) neural 18 architecture seems capable to process such information. However, there are 19 conflicting findings from patient, electrophysiological and neuroimaging studies. Here 20 we show for the first time that correct performance, workload and individual 21 performance differences are reflected in separate mechanisms of neural activity 22 within the MTL during maintenance of visual information in working memory. The 23 data suggest that low capacity subjects use the MTL to process the overload of 24 information. 25 Abstract 26The involvement of the medial temporal lobe (MTL) in working memory is 27 controversially discussed. Critically, it is unclear whether and how the MTL supports 28 performance of working memory. We recorded single neuron firing in 13 epilepsy 29 patients while they performed a visual working memory task. The number of colored 30

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“…Several models have been proposed for the implementation of working memory capabilities in neural networks. They have been divided into three categories: classical persistent activity, activity silent, and dynamic coding [13]. While models based on persistent activity do not engage any synaptic plasticity mechanism [14], activity-silent models and some dynamic coding models exploit short-term synaptic plasticity or neuronal adaptation [15]- [17].…”

Section: Related Workmentioning

confidence: 99%

H-Mem: Harnessing synaptic plasticity with Hebbian Memory Networks

Limbacher

Legenstein

2020

Preprint

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AbstractThe ability to base current computations on memories from the past is critical for many cognitive tasks such as story understanding. Hebbian-type synaptic plasticity is believed to underlie the retention of memories over medium and long time scales in the brain. However, it is unclear how such plasticity processes are integrated with computations in cortical networks. Here, we propose Hebbian Memory Networks (H-Mems), a simple neural network model that is built around a core hetero-associative network subject to Hebbian plasticity. We show that the network can be optimized to utilize the Hebbian plasticity processes for its computations. H-Mems can one-shot memorize associations between stimulus pairs and use these associations for decisions later on. Furthermore, they can solve demanding question-answering tasks on synthetic stories. Our study shows that neural network models are able to enrich their computations with memories through simple Hebbian plasticity processes.

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Between persistently active and activity‐silent frameworks: novel vistas on the cellular basis of working memory

Cited by 73 publications

References 70 publications

Theoretical distinction between functional states in working memory and their corresponding neural states

Theoretical distinction between functional states in working memory and their corresponding neural states

Neuronal firing in the medial temporal lobe reflects human working memory workload, performance and capacity

H-Mem: Harnessing synaptic plasticity with Hebbian Memory Networks

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