diff --git a/blog/2024-09-09-data_reuse_000458.md b/blog/2024-09-09-data_reuse_000458.md index 817e956..7b9a2ba 100644 --- a/blog/2024-09-09-data_reuse_000458.md +++ b/blog/2024-09-09-data_reuse_000458.md @@ -27,7 +27,7 @@ After their experiments, Claar and her team published their data on DANDI, ensur
Figure 1 -
Figure 1: Brain state modulates the ERP via cortico-thalamo-cortical interactions. +
Figure 1: Brain state modulates the ERP via cortico-thalamo-cortical interactions. (A) Butterfly plot of ERPs during non-running (quiet wakefulness), running (active wakefulness), and isoflurane-anesthetized states. (B) Normalized firing rate, reported as a z-score of the average, pre-stimulus firing rate, of all RS neurons recorded by the Neuropixels probes targeting the stimulated cortex (MO) and SM-TH. Reproduced from “Cortico-thalamo-cortical interactions modulate electrically evoked EEG responses in mice”. @@ -58,7 +58,7 @@ This data provides evidence for the hypothesized bidirectional relationship.
Figure 2 -
Figure 2: Shunting inhibition promotes local network desynchronization and response flexibility. +
Figure 2: Shunting inhibition promotes local network desynchronization and response flexibility. (A) High-density Neuropixels (NPXs) recordings were used to compare spiking activity in the same cortical neurons under awake and anesthetized conditions. (B) Example raster plots show the spiking activity of a population of neurons in somatosensory cortex (SS). Spiking activity is shown across three stimulation trials for each condition. (C) Neuronal synchrony on a trial-to-trial basis (top) and the entropy of the peri-stimulus histogram (bottom) were calculated for each of the 662 recorded neurons under awake and anesthetized conditions (17 probe recordings in 16 mice). Each dot corresponds to a single neuron and the dashed line indicates the line of equality.