UH Biocomputation Group - weakly electric fishttp://biocomputation.herts.ac.uk/2021-04-21T11:37:00+01:00Bursting Neurons Signal Input Slope2021-04-21T11:37:00+01:002021-04-21T11:37:00+01:00Volker Steubertag:biocomputation.herts.ac.uk,2021-04-21:/2021/04/21/bursting-neurons-signal-input-slope.html<p class="first last">Volker Steuber's Journal Club session where he will talk about a paper "Bursting Neurons Signal Input Slope"</p>
<p>This week on Journal Club session Volker Steuber will talk about a paper "Bursting Neurons Signal Input Slope".</p>
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<p>Brief bursts of high-frequency action potentials represent a common
firing mode of pyramidal neurons, and there are indications that they
represent a special neural code. It is therefore of interest to
determine whether there are particular spatial and temporal features
of neuronal inputs that trigger bursts. Recent work on pyramidal cells
indicates that bursts can be initiated by a specific spatial
arrangement of inputs in which there is coincident proximal and distal
dendritic excitation (Larkum et al., 1999). Here we have used a
computational model of an important class of bursting neurons to
investigate whether there are special temporal features of inputs that
trigger bursts. We find that when a model pyramidal neuron receives
sinusoidally or randomly varying inputs, bursts occur preferentially
on the positive slope of the input signal. We further find that the
number of spikes per burst can signal the magnitude of the slope in a
graded manner. We show how these computations can be understood in
terms of the biophysical mechanism of burst generation. There are
several examples in the literature suggesting that bursts indeed occur
preferentially on positive slopes (Guido et al., 1992; Gabbiani et
al., 1996). Our results suggest that this selectivity could be a
simple consequence of the biophysics of burst generation. Our
observations also raise the possibility that neurons use a burst
duration code useful for rapid information transmission. This
possibility could be further examined experimentally by looking for
correlations between burst duration and stimulus variables.</p>
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<p>Papers:</p>
<ul class="simple">
<li>A. Kepecs, X. Wang, J. Lisman, <a class="reference external" href="https://doi.org/10.1523/JNEUROSCI.22-20-09053.2002">"Bursting Neurons Signal Input Slope"</a>, 2002, The Journal of Neuroscience, 22, 9053--9062</li>
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<p><strong>Date:</strong> 2021/04/23 <br />
<strong>Time:</strong> 14:00 <br />
<strong>Location</strong>: online</p>