International audienceLocal supra-linear summation of excitatory inputs occurring in pyramidal cell dendrites, the so-called dendritic spikes, results in independent spiking dendritic sub-units, which turn pyramidal neurons into two-layer neural networks capable of computing linearly non-separable functions, such as the exclusive OR. Other neuron classes, such as interneurons, may possess only a few independent dendritic sub-units, or only passive dendrites where input summation is purely sub-linear, and where dendritic sub-units are only saturating. To determine if such neurons can also compute linearly non-separable functions, we enumerate, for a given parameter range, the Boolean functions implementable by a binary neuron model with a li...
International audience Advances in neuronal studies suggest that a single neuron can perform integra...
It has been conjectured that nonlinear processing in dendritic branches endows individual neurons wi...
A major challenge in neuroscience is to reverse engineer the brain and understand its information pr...
International audienceLocal supra-linear summation of excitatory inputs occurring in pyramidal cell ...
Local supra-linear summation of excitatory inputs occurring in pyramidal cell dendrites, the so-call...
The integration of excitatory inputs in dendrites is non-linear: multiple excita-tory inputs can pro...
International audienceNonlinear dendritic integration is thought to increase the computational abili...
Dendrites of pyramidal cells exhibit complex morphologies and contain a variety of ionic conductance...
Cortical neurons integrate thousands of synaptic inputs in their dendrites in highly nonlinear ways....
Dendrites of pyramidal cells exhibit complex morphologies and contain a variety of ionic conductance...
A fundamental question in understanding neuronal computations is how dendritic events influence the ...
Computational analyses of dendritic computations often assume stationary inputs to neurons, ignoring...
5 pages 3 figuresNeurons, modeled as linear threshold unit (LTU), can in theory compute all thresh- ...
<p>(A–B) The x-axis (Expected EPSP) is the arithmetic sum of two EPSPs induced by two distinct stimu...
2011-10-31Until recently, the accepted view of synaptic integration in most CNS neurons, including p...
International audience Advances in neuronal studies suggest that a single neuron can perform integra...
It has been conjectured that nonlinear processing in dendritic branches endows individual neurons wi...
A major challenge in neuroscience is to reverse engineer the brain and understand its information pr...
International audienceLocal supra-linear summation of excitatory inputs occurring in pyramidal cell ...
Local supra-linear summation of excitatory inputs occurring in pyramidal cell dendrites, the so-call...
The integration of excitatory inputs in dendrites is non-linear: multiple excita-tory inputs can pro...
International audienceNonlinear dendritic integration is thought to increase the computational abili...
Dendrites of pyramidal cells exhibit complex morphologies and contain a variety of ionic conductance...
Cortical neurons integrate thousands of synaptic inputs in their dendrites in highly nonlinear ways....
Dendrites of pyramidal cells exhibit complex morphologies and contain a variety of ionic conductance...
A fundamental question in understanding neuronal computations is how dendritic events influence the ...
Computational analyses of dendritic computations often assume stationary inputs to neurons, ignoring...
5 pages 3 figuresNeurons, modeled as linear threshold unit (LTU), can in theory compute all thresh- ...
<p>(A–B) The x-axis (Expected EPSP) is the arithmetic sum of two EPSPs induced by two distinct stimu...
2011-10-31Until recently, the accepted view of synaptic integration in most CNS neurons, including p...
International audience Advances in neuronal studies suggest that a single neuron can perform integra...
It has been conjectured that nonlinear processing in dendritic branches endows individual neurons wi...
A major challenge in neuroscience is to reverse engineer the brain and understand its information pr...