added masoli_et_al_2020b

2020/masoli_et_al_2020b/masoli_et_al_2020b.html

@@ -89,7 +89,7 @@ <h5 class="title-style">Cerebellar Golgi cell models predict dendritic processin
             </p>
             <p>
             <strong>DOI: </strong>
-            <a href="https://10.1101/2020.05.13.093906" target="_blank">
+            <a href="https://doi.org/10.1101/2020.05.13.093906" target="_blank">
                 <span class="color_link">https://10.1101/2020.05.13.093906</span>
             </a>
             </p>
@@ -98,16 +98,16 @@ <h5 class="title-style">Cerebellar Golgi cell models predict dendritic processin
             <a href="https://creativecommons.org/licenses/by/4.0/" target="_blank">
                 <span class="color_link">Creative Commons Attribution (CC BY) license</span>
             </a>&nbsp;applies for all files.&nbsp;Under this Open Access license
-            anyone&nbsp; may copy, distribute, or reuse the files as long as the authors and the original source are properly cited.
+            anyone&nbsp;may copy, distribute, or reuse the files as long as the authors and the original source are properly cited.
             </p>
         </div>
         <div class="note rounded">
             <h5>Abstract:</h5>
             The Golgi cells are the main inhibitory interneurons of the cerebellar granular layer. Although recent works have highlighted the complexity of their dendritic organization and synaptic inputs, the mechanisms through which these neurons integrate complex input patterns remained unknown. Here we have used 8 detailed morphological reconstructions to develop multicompartmental models of Golgi cells, in which Na, Ca, and K channels were distributed along dendrites, soma, axonal initial segment and axon. The models faithfully reproduced a rich pattern of electrophysiological and pharmacological properties and predicted the operating mechanisms of these neurons. Basal dendrites turned out to be more tightly electrically coupled to the axon initial segment than apical dendrites. During synaptic transmission, parallel fibers caused slow Ca-dependent depolarizations in apical dendrites that boosted the axon initial segment encoder and Na-spike backpropagation into basal dendrites, while inhibitory synapses effectively shunted backpropagating currents. This oriented dendritic processing set up a coincidence detector controlling voltage-dependent NMDA receptor unblock in basal dendrites, which, by regulating local calcium influx, may provide the basis for spike-timing dependent plasticity anticipated by theory.    
         </div>
         <h5>Resources</h5>
-        <p>Electrophysiological data available on the Knowledge graph. 
-        One model (more will be added) used in the paper, is available at the links reported below, grouped into the following categories:
+        <p>Electrophysiological data available in the HBP <a href="https://kg.ebrains.eu/search/?facet_type[0]=Dataset">Knowledge Graph</a>.
+        One of the models used in the paper is available at the links reported below, grouped into the following categories:
         </p>
         <ul class="collapsible" data-collapsible="expandable">
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@@ -116,7 +116,7 @@ <h5>Resources</h5>
                 </div>
                 <!-- option: leak_remove -->
                 <div class="collapsible-body ">
-                    <p>The morphology for the dendrites and soma is in .asc format. Modified from neuromorpho.org </p>
+                    <p>The morphology for the dendrites and the soma is in .asc format. Modified from neuromorpho.org </p>
                     <!-- <p>The explanation of how to setup a custom axon, or a specific dendritic sectionlist is available at the following link:</p> -->
 
                     <div style="margin-left:25px">

index.html

@@ -149,6 +149,18 @@ <h5 style="font-family: 'Merriweather', serif; text-align:center; line-height: 1
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+                                        <a href="2020/masoli_et_al_2020b/masoli_et_al_2020b.html" target="_blank" class="waves-effect waves-light">
+                                            Masoli S, Ottaviani A, D’Angelo E (2020) <i> Cerebellar Golgi cell models predict dendritic processing and mechanisms of synaptic plasticity.</i> bioRxiv.
+                                        </a>
+                                    </td>
+                                    <td class="ta-center">
+                                        <a href="https://collab.humanbrainproject.eu/#/collab/84490" target="_blank" class="waves-effect waves-light">
+                                            <img class="hbp-icon" src="static/imgs/hbp_diamond_120.png">
+                                        </a>
+                                        <td>
+                                </tr>
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                                         <a href="2020/saray_et_al_2020/saray_et_al_2020.html" target="_blank" class="waves-effect waves-light">