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@@ -113,6 +113,8 @@ <h2>Table of Contents</h2>
 
             <li><a href="#dandiset-000947">000947 - Reach-related Single Unit Activity in the Parkinsonian Macaque</a></li>
 
+            <li><a href="#dandiset-000971">000971 - Dopamine signaling in the dorsomedial striatum promotes compulsive behavior</a></li>
+
             <li><a href="#dandiset-001038">001038 - Unique functional responses differentially map onto genetic subtypes of dopamine neurons</a></li>
 
             <li><a href="#dandiset-001084">001084 - Targeted micro-fiber arrays for measuring and manipulating localized multi-scale neural dynamics over large, deep brain volumes during behavior</a></li>
@@ -500,6 +502,33 @@ <h3>Notebooks:</h3>
 
     </div>
 
+    <div id="dandiset-000971" class="dandiset">
+        <h2>Dopamine signaling in the dorsomedial striatum promotes compulsive behavior</h2>
+        <p><strong>ID:</strong> 000971</p>
+        <p><strong>Description:</strong> Compulsive behavior is a defining feature of disorders such as substance use disorders. Current evidence
+suggests that corticostriatal circuits control the expression of established compulsions, but little is known
+about the mechanisms regulating the development of compulsions. We hypothesized that dopamine, a critical modulator of striatal synaptic plasticity, could control alterations in corticostriatal circuits leading to the
+development of compulsions (defined here as continued reward seeking in the face of punishment). We used
+dual-site fiber photometry to measure dopamine axon activity in the dorsomedial striatum (DMS) and the
+dorsolateral striatum (DLS) as compulsions emerged. Individual variability in the speed with which compulsions emerged was predicted by DMS dopamine axon activity. Amplifying this dopamine signal accelerated
+animals’ transitions to compulsion, whereas inhibition delayed it. In contrast, amplifying DLS dopamine
+signaling had no effect on the emergence of compulsions. These results establish DMS dopamine signaling
+as a key controller of the development of compulsive reward seeking.</p>
+        <p><a href="https://dandiarchive.org/dandiset/000971" target="_blank">View on DANDI Archive</a></p>
+
+        <div class="notebooks">
+            <h3>Notebooks:</h3>
+            <ul>
+
+                <li><a href="https://github.com/dandi/example-notebooks/blob/master/000971/lernerlab/seiler_2024/fiber_photometry_example_notebook.ipynb" target="_blank">lernerlab/seiler_2024/fiber_photometry_example_notebook.ipynb</a></li>
+
+                <li><a href="https://github.com/dandi/example-notebooks/blob/master/000971/lernerlab/seiler_2024/optogenetics_example_notebook.ipynb" target="_blank">lernerlab/seiler_2024/optogenetics_example_notebook.ipynb</a></li>
+
+            </ul>
+        </div>
+
+    </div>
+
     <div id="dandiset-001038" class="dandiset">
         <h2>Unique functional responses differentially map onto genetic subtypes of dopamine neurons</h2>
         <p><strong>ID:</strong> 001038</p>