<p>(A) 16 glomerulus connected through SAs. The thick red line represents full connectivity between glomerulus. b) Architecture of the glomerular unit. The cells depicted are: mitral cell (MC), external tufted cell (ET), periglomerular cell (PG), and short axon (SA). Black balls represent inhibitory synapses and red balls indicate excitatory synapses. The ORN input synapses into MC, ET and PG cells. MC and PG cells form a negative feedback loop, where PG cells inhibit MC cells and in turn MC excite PG cells. ET cells contribute to the inhibition of MC through an excitatory connection to PG cells. Finally, connections between glomerulus are achieved via SA cells, which receive excitatory inputs from ET cells and transmit its outputs to PG an...
<p><b><i>A</i>:</b> Schematic representation of dendrodendritic synaptic connectivity among MCs, PGC...
How patterns of odour-evoked glomerular activity are transformed into patterns of mitral cell action...
<p>A, B) Model of the interaction between a smooth muscle cell (SMC) and an endothelial cell (EC) th...
<p>A. Synaptic schematic: Each glomerulus (dotted ellipse) receives input from olfactory receptor ne...
<p>The model is made of periglomerular (PG), mitral (M) and granular (Gr) cells. Blue arrows indicat...
<p>Schematic illustrating how excitation of mitral cells by CCK released from tufted cell terminals ...
<p>(A) In our circuit model, one mitral cell (black) receives excitatory sensory inputs (blue line) ...
<p>[Left]: The network consists of 5 glomerular channels, each incorporating 60 olfactory receptor n...
<p><i>Case A: A mitral/tufted cell related to a glomerular unit receiving no input.</i> This cell ex...
<p><b>(A)</b> Schematic of the MOB circuitry with GL surgical microcut, and preservation of the mitr...
<p><b>A</b>) Sketch of the recurrent bulbar network model with neurogenesis. Odor stimuli evoke glom...
Interneurons in the olfactory bulb are key elements of odor processing but their roles have not yet ...
<p>Within glomeruli, glutamatergic olfactory sensory neurons provide excitatory synaptic input to mi...
<p>Mitral cell: A. Visualization of a simulated <i>slice</i> network. We simulated ORN shock input t...
<p>Excitatory connections are represented with arrows and inhibitory connections with circles. Just ...
<p><b><i>A</i>:</b> Schematic representation of dendrodendritic synaptic connectivity among MCs, PGC...
How patterns of odour-evoked glomerular activity are transformed into patterns of mitral cell action...
<p>A, B) Model of the interaction between a smooth muscle cell (SMC) and an endothelial cell (EC) th...
<p>A. Synaptic schematic: Each glomerulus (dotted ellipse) receives input from olfactory receptor ne...
<p>The model is made of periglomerular (PG), mitral (M) and granular (Gr) cells. Blue arrows indicat...
<p>Schematic illustrating how excitation of mitral cells by CCK released from tufted cell terminals ...
<p>(A) In our circuit model, one mitral cell (black) receives excitatory sensory inputs (blue line) ...
<p>[Left]: The network consists of 5 glomerular channels, each incorporating 60 olfactory receptor n...
<p><i>Case A: A mitral/tufted cell related to a glomerular unit receiving no input.</i> This cell ex...
<p><b>(A)</b> Schematic of the MOB circuitry with GL surgical microcut, and preservation of the mitr...
<p><b>A</b>) Sketch of the recurrent bulbar network model with neurogenesis. Odor stimuli evoke glom...
Interneurons in the olfactory bulb are key elements of odor processing but their roles have not yet ...
<p>Within glomeruli, glutamatergic olfactory sensory neurons provide excitatory synaptic input to mi...
<p>Mitral cell: A. Visualization of a simulated <i>slice</i> network. We simulated ORN shock input t...
<p>Excitatory connections are represented with arrows and inhibitory connections with circles. Just ...
<p><b><i>A</i>:</b> Schematic representation of dendrodendritic synaptic connectivity among MCs, PGC...
How patterns of odour-evoked glomerular activity are transformed into patterns of mitral cell action...
<p>A, B) Model of the interaction between a smooth muscle cell (SMC) and an endothelial cell (EC) th...