A Spiking Working Memory Model Based on Hebbian Short-Term Potentiation

Fiebig, Florian; Lansner, Anders

doi:10.1523/jneurosci.1989-16.2016

Cited by 103 publications

(77 citation statements)

References 69 publications

(114 reference statements)

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“…Indeed, models show that a mixture of a rate code and STSP can maintain memories. For instance, Fiebig and Lansner proposed a model of WM that uses a combination of rate coding and a Hebbian form of spike timing–dependent STSP. This network is able to hold multiple items in memory at the same time.…”

Section: Interactions Between Wm and Long‐term Memorymentioning

confidence: 99%

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

Kamiński

Rutishauser

2019

Annals of the New York Academy of Sciences

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Recent work has revealed important new discoveries on the cellular mechanisms of working memory (WM). These findings have motivated several seemingly conflicting theories on the mechanisms of short‐term memory maintenance. Here, we summarize the key insights gained from these new experiments and critically evaluate them in light of three hypotheses: classical persistent activity, activity‐silent, and dynamic coding. The experiments discussed include the first direct demonstration of persistently active neurons in the human medial temporal lobe that form static attractors with relevance to WM, single‐neuron recordings in the macaque prefrontal cortex that show evidence for both persistent and more dynamic types of WM representations, and noninvasive neuroimaging in humans that argues for activity‐silent representations. A key insight that emerges from these new results is that there are several neural mechanisms that support the maintenance of information in WM. Finally, based on established cognitive theories of WM, we propose a coherent model that encompasses these seemingly contradictory results. We propose that the three neuronal mechanisms of persistent activity, activity‐silent, and dynamic coding map well onto the cognitive levels of information processing (within focus of attention, activated long‐term memory, and central executive) that Cowan's WM model proposes.

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Section: Interactions Between Wm and Long‐term Memorymentioning

confidence: 99%

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

Kamiński

Rutishauser

2019

Annals of the New York Academy of Sciences

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“…An important question for the EBH hypothesis is: what is the structure of this conscious control process, and how can it be described in a way that is biologically plausible and useful as a component of a computational model? We do not speculate on the answer to this question here, but note that this process is closely related to phenomena studied under many labels, including conscious control (Schneider and Shiffrin, 1977;Shepherd, 2015), imagination (Ayman-Nolley, 1992;Asma, 2017), working memory (Fiebig and Lansner, 2017;Velichkovsky, 2017;Masse et al, 2019), and consciousness (Dehaene and Naccache, 2001;Tallon-Baudry, 2011;Koch et al, 2016;Tononi et al, 2016;Velichkovsky, 2017), and prior work in these areas may provide clues as to how this process emerges and operates, and how it may contribute mechanistically to EBH learning.…”

Section: Discussionmentioning

confidence: 93%

Example Based Hebbian Learning may be sufficient to support Human Intelligence

Wong

2019

Preprint

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In this hypothesis paper we argue that a simple Hebbian learning mechanism, along with reinforcement through well-known neuromodulatory systems, can form the basis of a computational theory of learning that can support both low level learning and the development of human level intelligence. We show that when driven by example behavior Hebbian learning rules can support procedural, episodic and semantic memory. For humans, we hypothesize that the abilities to manipulate an off-line world model and to abstract using language allow for the generation and communication of rich example behavior, respectively, and thereby support human learning and a gradual increase of collective human intelligence across generations. We also compare the properties of Example Based Hebbian (EBH) learning with those of backpropagation-based learning and argue that the EBH mechanism is more consistent with observed characteristics of human learning.

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“…Here we have followed the modelling philosophy aimed at distilling the architecture of the network to its essential characteristics that support and control the phenomenon of interest (sequence learning). In the previous models of particular relevance to our work, complex spike based dynamics and rich biological detail were promoted to provide insights into the biophysical underpinnings of sequence learning in the cortex (Tully et al, 2016) and as a model of memory consolidation (Fiebig and Lansner, 2017). While the aforementioned contributions provide a more direct mapping between biology and the network, our approach, which reduces the network to its essential characteristics, necessarily dilutes that mapping.…”

Section: Previous Work and Biological Contextmentioning

confidence: 99%

Probabilistic associative learning suffices for learning the temporal structure of multiple sequences

Martínez

Lansner

Herman

2019

Preprint

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Many brain phenomena both at the cognitive and behavior level exhibit remarkable sequential characteristics. While the mechanisms behind the sequential nature of the underlying brain activity are likely multifarious and multi-scale, in this work we attempt to characterize to what degree some of this properties can be explained as a consequence of simple associative learning. To this end, we employ a parsimonious firing-rate attractor network equipped with the Hebbian-like Bayesian Confidence Propagating Neural Network (BCPNN) learning rule relying on synaptic traces with asymmetric temporal characteristics. The proposed network model is able to encode and reproduce temporal aspects of the input, and offers internal control of the recall dynamics by gain modulation. We provide an analytical characterisation of the relationship between the structure of the weight matrix, the dynamical network parameters and the temporal aspects of sequence recall. We also present a computational study of the performance of the system under the effects of noise for an extensive region of the parameter space. Finally, we show how the inclusion of modularity in our network structure facilitates the learning and recall of multiple overlapping sequences even in a noisy regime.

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A Spiking Working Memory Model Based on Hebbian Short-Term Potentiation

Cited by 103 publications

References 69 publications

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

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

Example Based Hebbian Learning may be sufficient to support Human Intelligence

Probabilistic associative learning suffices for learning the temporal structure of multiple sequences

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