Spike-frequency adaptation supports network computations on temporally dispersed information

Darjan Salaj; Anand Subramoney; Ceca Kraisnikovic; Guillaume Emmanuel Fernand Bellec; Robert Legenstein; Wolfgang Maass

doi:10.7554/eLife.65459

Spike-frequency adaptation supports network computations on temporally dispersed information

Darjan Salaj, Anand Subramoney, Ceca Kraisnikovic, Guillaume Emmanuel Fernand Bellec, Robert Legenstein, Wolfgang Maass^*

^*Corresponding author for this work

Institute of Theoretical Computer Science (7080)

Research output: Contribution to journal › Article › peer-review

Abstract

For solving tasks such as recognizing a song, answering a question, or inverting a sequence of symbols, cortical microcircuits need to integrate and manipulate information that was dispersed over time during the preceding seconds. Creating biologically realistic models for the underlying computations, especially with spiking neurons and for behaviorally relevant integration time spans, is notoriously difficult. We examine the role of spike frequency adaptation in such computations and find that it has a surprisingly large impact. The inclusion of this well-known property of a substantial fraction of neurons in the neocortex – especially in higher areas of the human neocortex – moves the performance of spiking neural network models for computations on network inputs that are temporally dispersed from a fairly low level up to the performance level of the human brain.

Original language	English
Article number	e65459
Number of pages	33
Journal	eLife
Volume	10
DOIs	https://doi.org/10.7554/eLife.65459
Publication status	Published - Jul 2021

ASJC Scopus subject areas

Biochemistry, Genetics and Molecular Biology(all)
Immunology and Microbiology(all)
Neuroscience(all)

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10.7554/eLife.65459Licence: CC BY 4.0

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abstract = "For solving tasks such as recognizing a song, answering a question, or inverting a sequence of symbols, cortical microcircuits need to integrate and manipulate information that was dispersed over time during the preceding seconds. Creating biologically realistic models for the underlying computations, especially with spiking neurons and for behaviorally relevant integration time spans, is notoriously difficult. We examine the role of spike frequency adaptation in such computations and find that it has a surprisingly large impact. The inclusion of this well-known property of a substantial fraction of neurons in the neocortex – especially in higher areas of the human neocortex – moves the performance of spiking neural network models for computations on network inputs that are temporally dispersed from a fairly low level up to the performance level of the human brain.",

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AU - Subramoney, Anand

AU - Kraisnikovic, Ceca

AU - Bellec, Guillaume Emmanuel Fernand

AU - Legenstein, Robert

AU - Maass, Wolfgang

PY - 2021/7

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AB - For solving tasks such as recognizing a song, answering a question, or inverting a sequence of symbols, cortical microcircuits need to integrate and manipulate information that was dispersed over time during the preceding seconds. Creating biologically realistic models for the underlying computations, especially with spiking neurons and for behaviorally relevant integration time spans, is notoriously difficult. We examine the role of spike frequency adaptation in such computations and find that it has a surprisingly large impact. The inclusion of this well-known property of a substantial fraction of neurons in the neocortex – especially in higher areas of the human neocortex – moves the performance of spiking neural network models for computations on network inputs that are temporally dispersed from a fairly low level up to the performance level of the human brain.

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Spike-frequency adaptation supports network computations on temporally dispersed information

Abstract

ASJC Scopus subject areas

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