<p>Each subfigure shows the frequency of neuron spike counts over the 5s simulation for four distinct network topologies. Data for excitatory neurons are shown in the left column and data for inhibitory neurons in the right column. The first row shows data for the random network, the second row the lattice network, the third row the rewired lattice network with and , and the fourth row the network with embedded modular excitatory subnetworks. The rewired lattice and modular networks each have numerous neurons that spike much more frequently than those in the random or lattice networks, and also produce many more spikes in total.</p
<p>Example of a toy-network illustrating that the degree to which any given metric of neuron embedde...
<p>Left: (Top) Raster plot of randomly chosen neurons (out of a total of neurons in the simulation...
<div><p>(A) Mean spike count plotted against static input signals s without (<i>A</i> = 0, thin line...
<p>This figure shows the frequency of spike counts for different structurally-defined neuron classes...
<p>This figure shows each spike from a single 5.1s simulation for the rewired ring-lattice network w...
Top left: Raster plots show spike times of 50 out of 10, 000 excitatory (E) and 50 out of 2, 500 inh...
<p>This figure shows each spike from a single 5.1s simulation with the deterministic ring lattice ne...
<p>This figure shows each spike from a single 5.1s simulation with the rewired ring-lattice network,...
<p>This figure shows the ‘functional in-degree’ from different neuron classes to active neurons, fro...
<p><b>A-B</b>: The inter-spike-interval CVs from simulated spike trains versus the neuron’s in degre...
(a) The demonstration network consists of populations of excitatory (red dots), inhibitory (blue dot...
<p><i>N</i> = 10000, <i>K</i> = 800, <i>J</i><sub>0</sub> = 2, <i>I</i><sub>0</sub> = 0.3. Voltage t...
<p>(A) Network response (PSTH) for identical stimulation of 30 different subpopulations of 250 neuro...
<p>A: spike trains of six randomly selected excitatory neurons during 200 time steps. B: example of ...
<p><b>A</b> Top: Bright field and fluorescence images of a small region of a neuronal culture at day...
<p>Example of a toy-network illustrating that the degree to which any given metric of neuron embedde...
<p>Left: (Top) Raster plot of randomly chosen neurons (out of a total of neurons in the simulation...
<div><p>(A) Mean spike count plotted against static input signals s without (<i>A</i> = 0, thin line...
<p>This figure shows the frequency of spike counts for different structurally-defined neuron classes...
<p>This figure shows each spike from a single 5.1s simulation for the rewired ring-lattice network w...
Top left: Raster plots show spike times of 50 out of 10, 000 excitatory (E) and 50 out of 2, 500 inh...
<p>This figure shows each spike from a single 5.1s simulation with the deterministic ring lattice ne...
<p>This figure shows each spike from a single 5.1s simulation with the rewired ring-lattice network,...
<p>This figure shows the ‘functional in-degree’ from different neuron classes to active neurons, fro...
<p><b>A-B</b>: The inter-spike-interval CVs from simulated spike trains versus the neuron’s in degre...
(a) The demonstration network consists of populations of excitatory (red dots), inhibitory (blue dot...
<p><i>N</i> = 10000, <i>K</i> = 800, <i>J</i><sub>0</sub> = 2, <i>I</i><sub>0</sub> = 0.3. Voltage t...
<p>(A) Network response (PSTH) for identical stimulation of 30 different subpopulations of 250 neuro...
<p>A: spike trains of six randomly selected excitatory neurons during 200 time steps. B: example of ...
<p><b>A</b> Top: Bright field and fluorescence images of a small region of a neuronal culture at day...
<p>Example of a toy-network illustrating that the degree to which any given metric of neuron embedde...
<p>Left: (Top) Raster plot of randomly chosen neurons (out of a total of neurons in the simulation...
<div><p>(A) Mean spike count plotted against static input signals s without (<i>A</i> = 0, thin line...