Computational implications of biophysical diversity and multiple timescales in neurons and synapses for circuit performance

Julijana Gjorgjieva; Guillaume Drion; Eve Marder

doi:10.1016/j.conb.2015.12.008

Computational implications of biophysical diversity and multiple timescales in neurons and synapses for circuit performance

Julijana Gjorgjieva, Guillaume Drion, Eve Marder

Research output: Contribution to journal › Review article › peer-review

100 Scopus citations

Abstract

Despite advances in experimental and theoretical neuroscience, we are still trying to identify key biophysical details that are important for characterizing the operation of brain circuits. Biological mechanisms at the level of single neurons and synapses can be combined as 'building blocks' to generate circuit function. We focus on the importance of capturing multiple timescales when describing these intrinsic and synaptic components. Whether inherent in the ionic currents, the neuron's complex morphology, or the neurotransmitter composition of synapses, these multiple timescales prove crucial for capturing the variability and richness of circuit output and enhancing the information-carrying capacity observed across nervous systems.

Original language	English
Pages (from-to)	44-52
Number of pages	9
Journal	Current Opinion in Neurobiology
Volume	37
DOIs	https://doi.org/10.1016/j.conb.2015.12.008
State	Published - 1 Apr 2016
Externally published	Yes

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abstract = "Despite advances in experimental and theoretical neuroscience, we are still trying to identify key biophysical details that are important for characterizing the operation of brain circuits. Biological mechanisms at the level of single neurons and synapses can be combined as 'building blocks' to generate circuit function. We focus on the importance of capturing multiple timescales when describing these intrinsic and synaptic components. Whether inherent in the ionic currents, the neuron's complex morphology, or the neurotransmitter composition of synapses, these multiple timescales prove crucial for capturing the variability and richness of circuit output and enhancing the information-carrying capacity observed across nervous systems.",

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AU - Marder, Eve

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Computational implications of biophysical diversity and multiple timescales in neurons and synapses for circuit performance

Abstract

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