In Vivo Astrocyte Dynamics During Behavior
This section is represented as a source-backed SciDEX wiki artifact. The full source remains in the original computational-review repository.
Source: https://github.com/AllenNeuralDynamics/ComputationalReviewAstrocytes/blob/1a55da0634a3bc04e5688792ed12141ce271d28e/content/09_in_vivo_dynamics.md
Citation anchors captured: 120
Citation contexts
-
1CitationIf astrocytes gate plasticity (Section {ref}
sec:plasticity), what are they actually doing during ongoing behaviour such that this gating can matter? The evidence compiled here frames an answer that departs substantially from the stimulus-specific picture carried over from acute-slice work (Section {ref}sec:calcium-signaling). In awake head-fixed rodents, astrocyte Ca$^{2+}$ is dominated by global arousal and loc...content/09_in_vivo_dynamics.md:line 4Open reference If astrocytes gate plasticity (Section{ref}sec:plasticity), what are they actually doing during ongoing behaviour such that this gating can matter? The evidence compiled here frames an answer that departs substantially from the stimulus-specific picture carried over from acute-slice work (Section{ref}sec:calcium-signaling). In awake head-fixed rodents, astrocyte Ca^{2+} is dominated by global arousal and loc... -
2CitationIf astrocytes gate plasticity (Section {ref}
sec:plasticity), what are they actually doing during ongoing behaviour such that this gating can matter? The evidence compiled here frames an answer that departs substantially from the stimulus-specific picture carried over from acute-slice work (Section {ref}sec:calcium-signaling). In awake head-fixed rodents, astrocyte Ca$^{2+}$ is dominated by global arousal and loc...content/09_in_vivo_dynamics.md:line 4Open reference If astrocytes gate plasticity (Section{ref}sec:plasticity), what are they actually doing during ongoing behaviour such that this gating can matter? The evidence compiled here frames an answer that departs substantially from the stimulus-specific picture carried over from acute-slice work (Section{ref}sec:calcium-signaling). In awake head-fixed rodents, astrocyte Ca^{2+} is dominated by global arousal and loc... -
3CitationIf astrocytes gate plasticity (Section {ref}
sec:plasticity), what are they actually doing during ongoing behaviour such that this gating can matter? The evidence compiled here frames an answer that departs substantially from the stimulus-specific picture carried over from acute-slice work (Section {ref}sec:calcium-signaling). In awake head-fixed rodents, astrocyte Ca$^{2+}$ is dominated by global arousal and loc...content/09_in_vivo_dynamics.md:line 4Open reference If astrocytes gate plasticity (Section{ref}sec:plasticity), what are they actually doing during ongoing behaviour such that this gating can matter? The evidence compiled here frames an answer that departs substantially from the stimulus-specific picture carried over from acute-slice work (Section{ref}sec:calcium-signaling). In awake head-fixed rodents, astrocyte Ca^{2+} is dominated by global arousal and loc... -
4CitationIf astrocytes gate plasticity (Section {ref}
sec:plasticity), what are they actually doing during ongoing behaviour such that this gating can matter? The evidence compiled here frames an answer that departs substantially from the stimulus-specific picture carried over from acute-slice work (Section {ref}sec:calcium-signaling). In awake head-fixed rodents, astrocyte Ca$^{2+}$ is dominated by global arousal and loc...content/09_in_vivo_dynamics.md:line 4Open reference If astrocytes gate plasticity (Section{ref}sec:plasticity), what are they actually doing during ongoing behaviour such that this gating can matter? The evidence compiled here frames an answer that departs substantially from the stimulus-specific picture carried over from acute-slice work (Section{ref}sec:calcium-signaling). In awake head-fixed rodents, astrocyte Ca^{2+} is dominated by global arousal and loc... -
5CitationIf astrocytes gate plasticity (Section {ref}
sec:plasticity), what are they actually doing during ongoing behaviour such that this gating can matter? The evidence compiled here frames an answer that departs substantially from the stimulus-specific picture carried over from acute-slice work (Section {ref}sec:calcium-signaling). In awake head-fixed rodents, astrocyte Ca$^{2+}$ is dominated by global arousal and loc...content/09_in_vivo_dynamics.md:line 4Open reference If astrocytes gate plasticity (Section{ref}sec:plasticity), what are they actually doing during ongoing behaviour such that this gating can matter? The evidence compiled here frames an answer that departs substantially from the stimulus-specific picture carried over from acute-slice work (Section{ref}sec:calcium-signaling). In awake head-fixed rodents, astrocyte Ca^{2+} is dominated by global arousal and loc... -
6Citationobjective [dombeck2007neuron], and this preparation has since been populated by genetically encoded indicators driven from astrocytecontent/09_in_vivo_dynamics.md:line 12Open reference objective 6Citationobjective [dombeck2007neuron], and this preparation has since been populated by genetically encoded indicators driven from astrocytecontent/09_in_vivo_dynamics.md:line 12Open reference, and this preparation has since been populated by genetically encoded indicators driven from astrocyte
-
7Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference kinetics 7Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference, 8Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference, 9Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference, 10Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference, 11Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference, 12Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference
-
8Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference kinetics 2CitationIf astrocytes gate plasticity (Section {ref}
sec:plasticity), what are they actually doing during ongoing behaviour such that this gating can matter? The evidence compiled here frames an answer that departs substantially from the stimulus-specific picture carried over from acute-slice work (Section {ref}sec:calcium-signaling). In awake head-fixed rodents, astrocyte Ca$^{2+}$ is dominated by global arousal and loc...content/09_in_vivo_dynamics.md:line 4Open reference0 -
2CitationIf astrocytes gate plasticity (Section {ref}
sec:plasticity), what are they actually doing during ongoing behaviour such that this gating can matter? The evidence compiled here frames an answer that departs substantially from the stimulus-specific picture carried over from acute-slice work (Section {ref}sec:calcium-signaling). In awake head-fixed rodents, astrocyte Ca$^{2+}$ is dominated by global arousal and loc...content/09_in_vivo_dynamics.md:line 4Open reference1 kinetics 2CitationIf astrocytes gate plasticity (Section {ref}sec:plasticity), what are they actually doing during ongoing behaviour such that this gating can matter? The evidence compiled here frames an answer that departs substantially from the stimulus-specific picture carried over from acute-slice work (Section {ref}sec:calcium-signaling). In awake head-fixed rodents, astrocyte Ca$^{2+}$ is dominated by global arousal and loc...content/09_in_vivo_dynamics.md:line 4Open reference2 -
2CitationIf astrocytes gate plasticity (Section {ref}
sec:plasticity), what are they actually doing during ongoing behaviour such that this gating can matter? The evidence compiled here frames an answer that departs substantially from the stimulus-specific picture carried over from acute-slice work (Section {ref}sec:calcium-signaling). In awake head-fixed rodents, astrocyte Ca$^{2+}$ is dominated by global arousal and loc...content/09_in_vivo_dynamics.md:line 4Open reference3 kinetics 2CitationIf astrocytes gate plasticity (Section {ref}sec:plasticity), what are they actually doing during ongoing behaviour such that this gating can matter? The evidence compiled here frames an answer that departs substantially from the stimulus-specific picture carried over from acute-slice work (Section {ref}sec:calcium-signaling). In awake head-fixed rodents, astrocyte Ca$^{2+}$ is dominated by global arousal and loc...content/09_in_vivo_dynamics.md:line 4Open reference4 -
2CitationIf astrocytes gate plasticity (Section {ref}
sec:plasticity), what are they actually doing during ongoing behaviour such that this gating can matter? The evidence compiled here frames an answer that departs substantially from the stimulus-specific picture carried over from acute-slice work (Section {ref}sec:calcium-signaling). In awake head-fixed rodents, astrocyte Ca$^{2+}$ is dominated by global arousal and loc...content/09_in_vivo_dynamics.md:line 4Open reference5 kinetics 2CitationIf astrocytes gate plasticity (Section {ref}sec:plasticity), what are they actually doing during ongoing behaviour such that this gating can matter? The evidence compiled here frames an answer that departs substantially from the stimulus-specific picture carried over from acute-slice work (Section {ref}sec:calcium-signaling). In awake head-fixed rodents, astrocyte Ca$^{2+}$ is dominated by global arousal and loc...content/09_in_vivo_dynamics.md:line 4Open reference6 -
2CitationIf astrocytes gate plasticity (Section {ref}
sec:plasticity), what are they actually doing during ongoing behaviour such that this gating can matter? The evidence compiled here frames an answer that departs substantially from the stimulus-specific picture carried over from acute-slice work (Section {ref}sec:calcium-signaling). In awake head-fixed rodents, astrocyte Ca$^{2+}$ is dominated by global arousal and loc...content/09_in_vivo_dynamics.md:line 4Open reference7 kinetics 2CitationIf astrocytes gate plasticity (Section {ref}sec:plasticity), what are they actually doing during ongoing behaviour such that this gating can matter? The evidence compiled here frames an answer that departs substantially from the stimulus-specific picture carried over from acute-slice work (Section {ref}sec:calcium-signaling). In awake head-fixed rodents, astrocyte Ca$^{2+}$ is dominated by global arousal and loc...content/09_in_vivo_dynamics.md:line 4Open reference8 -
2CitationIf astrocytes gate plasticity (Section {ref}
sec:plasticity), what are they actually doing during ongoing behaviour such that this gating can matter? The evidence compiled here frames an answer that departs substantially from the stimulus-specific picture carried over from acute-slice work (Section {ref}sec:calcium-signaling). In awake head-fixed rodents, astrocyte Ca$^{2+}$ is dominated by global arousal and loc...content/09_in_vivo_dynamics.md:line 4Open reference9 licking 3CitationIf astrocytes gate plasticity (Section {ref}sec:plasticity), what are they actually doing during ongoing behaviour such that this gating can matter? The evidence compiled here frames an answer that departs substantially from the stimulus-specific picture carried over from acute-slice work (Section {ref}sec:calcium-signaling). In awake head-fixed rodents, astrocyte Ca$^{2+}$ is dominated by global arousal and loc...content/09_in_vivo_dynamics.md:line 4Open reference0. -
3CitationIf astrocytes gate plasticity (Section {ref}
sec:plasticity), what are they actually doing during ongoing behaviour such that this gating can matter? The evidence compiled here frames an answer that departs substantially from the stimulus-specific picture carried over from acute-slice work (Section {ref}sec:calcium-signaling). In awake head-fixed rodents, astrocyte Ca$^{2+}$ is dominated by global arousal and loc...content/09_in_vivo_dynamics.md:line 4Open reference1 licking 3CitationIf astrocytes gate plasticity (Section {ref}sec:plasticity), what are they actually doing during ongoing behaviour such that this gating can matter? The evidence compiled here frames an answer that departs substantially from the stimulus-specific picture carried over from acute-slice work (Section {ref}sec:calcium-signaling). In awake head-fixed rodents, astrocyte Ca$^{2+}$ is dominated by global arousal and loc...content/09_in_vivo_dynamics.md:line 4Open reference2. -
3CitationIf astrocytes gate plasticity (Section {ref}
sec:plasticity), what are they actually doing during ongoing behaviour such that this gating can matter? The evidence compiled here frames an answer that departs substantially from the stimulus-specific picture carried over from acute-slice work (Section {ref}sec:calcium-signaling). In awake head-fixed rodents, astrocyte Ca$^{2+}$ is dominated by global arousal and loc...content/09_in_vivo_dynamics.md:line 4Open reference3 licking 3CitationIf astrocytes gate plasticity (Section {ref}sec:plasticity), what are they actually doing during ongoing behaviour such that this gating can matter? The evidence compiled here frames an answer that departs substantially from the stimulus-specific picture carried over from acute-slice work (Section {ref}sec:calcium-signaling). In awake head-fixed rodents, astrocyte Ca$^{2+}$ is dominated by global arousal and loc...content/09_in_vivo_dynamics.md:line 4Open reference4. -
3CitationIf astrocytes gate plasticity (Section {ref}
sec:plasticity), what are they actually doing during ongoing behaviour such that this gating can matter? The evidence compiled here frames an answer that departs substantially from the stimulus-specific picture carried over from acute-slice work (Section {ref}sec:calcium-signaling). In awake head-fixed rodents, astrocyte Ca$^{2+}$ is dominated by global arousal and loc...content/09_in_vivo_dynamics.md:line 4Open reference5 microscopy 3CitationIf astrocytes gate plasticity (Section {ref}sec:plasticity), what are they actually doing during ongoing behaviour such that this gating can matter? The evidence compiled here frames an answer that departs substantially from the stimulus-specific picture carried over from acute-slice work (Section {ref}sec:calcium-signaling). In awake head-fixed rodents, astrocyte Ca$^{2+}$ is dominated by global arousal and loc...content/09_in_vivo_dynamics.md:line 4Open reference6), and whether stimuli are -
3CitationIf astrocytes gate plasticity (Section {ref}
sec:plasticity), what are they actually doing during ongoing behaviour such that this gating can matter? The evidence compiled here frames an answer that departs substantially from the stimulus-specific picture carried over from acute-slice work (Section {ref}sec:calcium-signaling). In awake head-fixed rodents, astrocyte Ca$^{2+}$ is dominated by global arousal and loc...content/09_in_vivo_dynamics.md:line 4Open reference7 open- or closed-loop. These choices are not interchangeable: Lck-tethered indicators capture faster, smaller process events that cytosolic reporters underreport 3CitationIf astrocytes gate plasticity (Section {ref}sec:plasticity), what are they actually doing during ongoing behaviour such that this gating can matter? The evidence compiled here frames an answer that departs substantially from the stimulus-specific picture carried over from acute-slice work (Section {ref}sec:calcium-signaling). In awake head-fixed rodents, astrocyte Ca$^{2+}$ is dominated by global arousal and loc...content/09_in_vivo_dynamics.md:line 4Open reference8, and soma measurements bias towards long, coordinated transients that fine-process recordings fractionate into many distinct subcellular signals 3CitationIf astrocytes gate plasticity (Section {ref}sec:plasticity), what are they actually doing during ongoing behaviour such that this gating can matter? The evidence compiled here frames an answer that departs substantially from the stimulus-specific picture carried over from acute-slice work (Section {ref}sec:calcium-signaling). In awake head-fixed rodents, astrocyte Ca$^{2+}$ is dominated by global arousal and loc...content/09_in_vivo_dynamics.md:line 4Open reference9. D... -
4CitationIf astrocytes gate plasticity (Section {ref}
sec:plasticity), what are they actually doing during ongoing behaviour such that this gating can matter? The evidence compiled here frames an answer that departs substantially from the stimulus-specific picture carried over from acute-slice work (Section {ref}sec:calcium-signaling). In awake head-fixed rodents, astrocyte Ca$^{2+}$ is dominated by global arousal and loc...content/09_in_vivo_dynamics.md:line 4Open reference0 open- or closed-loop. These choices are not interchangeable: Lck-tethered indicators capture faster, smaller process events that cytosolic reporters underreport 4CitationIf astrocytes gate plasticity (Section {ref}sec:plasticity), what are they actually doing during ongoing behaviour such that this gating can matter? The evidence compiled here frames an answer that departs substantially from the stimulus-specific picture carried over from acute-slice work (Section {ref}sec:calcium-signaling). In awake head-fixed rodents, astrocyte Ca$^{2+}$ is dominated by global arousal and loc...content/09_in_vivo_dynamics.md:line 4Open reference1, and soma measurements bias towards long, coordinated transients that fine-process recordings fractionate into many distinct subcellular signals 4CitationIf astrocytes gate plasticity (Section {ref}sec:plasticity), what are they actually doing during ongoing behaviour such that this gating can matter? The evidence compiled here frames an answer that departs substantially from the stimulus-specific picture carried over from acute-slice work (Section {ref}sec:calcium-signaling). In awake head-fixed rodents, astrocyte Ca$^{2+}$ is dominated by global arousal and loc...content/09_in_vivo_dynamics.md:line 4Open reference2. D... -
4CitationIf astrocytes gate plasticity (Section {ref}
sec:plasticity), what are they actually doing during ongoing behaviour such that this gating can matter? The evidence compiled here frames an answer that departs substantially from the stimulus-specific picture carried over from acute-slice work (Section {ref}sec:calcium-signaling). In awake head-fixed rodents, astrocyte Ca$^{2+}$ is dominated by global arousal and loc...content/09_in_vivo_dynamics.md:line 4Open reference3 open- or closed-loop. These choices are not interchangeable: Lck-tethered indicators capture faster, smaller process events that cytosolic reporters underreport 4CitationIf astrocytes gate plasticity (Section {ref}sec:plasticity), what are they actually doing during ongoing behaviour such that this gating can matter? The evidence compiled here frames an answer that departs substantially from the stimulus-specific picture carried over from acute-slice work (Section {ref}sec:calcium-signaling). In awake head-fixed rodents, astrocyte Ca$^{2+}$ is dominated by global arousal and loc...content/09_in_vivo_dynamics.md:line 4Open reference4, and soma measurements bias towards long, coordinated transients that fine-process recordings fractionate into many distinct subcellular signals 4CitationIf astrocytes gate plasticity (Section {ref}sec:plasticity), what are they actually doing during ongoing behaviour such that this gating can matter? The evidence compiled here frames an answer that departs substantially from the stimulus-specific picture carried over from acute-slice work (Section {ref}sec:calcium-signaling). In awake head-fixed rodents, astrocyte Ca$^{2+}$ is dominated by global arousal and loc...content/09_in_vivo_dynamics.md:line 4Open reference5. D... -
4CitationIf astrocytes gate plasticity (Section {ref}
sec:plasticity), what are they actually doing during ongoing behaviour such that this gating can matter? The evidence compiled here frames an answer that departs substantially from the stimulus-specific picture carried over from acute-slice work (Section {ref}sec:calcium-signaling). In awake head-fixed rodents, astrocyte Ca$^{2+}$ is dominated by global arousal and loc...content/09_in_vivo_dynamics.md:line 4Open reference6 open- or closed-loop. These choices are not interchangeable: Lck-tethered indicators capture faster, smaller process events that cytosolic reporters underreport 4CitationIf astrocytes gate plasticity (Section {ref}sec:plasticity), what are they actually doing during ongoing behaviour such that this gating can matter? The evidence compiled here frames an answer that departs substantially from the stimulus-specific picture carried over from acute-slice work (Section {ref}sec:calcium-signaling). In awake head-fixed rodents, astrocyte Ca$^{2+}$ is dominated by global arousal and loc...content/09_in_vivo_dynamics.md:line 4Open reference7, and soma measurements bias towards long, coordinated transients that fine-process recordings fractionate into many distinct subcellular signals 4CitationIf astrocytes gate plasticity (Section {ref}sec:plasticity), what are they actually doing during ongoing behaviour such that this gating can matter? The evidence compiled here frames an answer that departs substantially from the stimulus-specific picture carried over from acute-slice work (Section {ref}sec:calcium-signaling). In awake head-fixed rodents, astrocyte Ca$^{2+}$ is dominated by global arousal and loc...content/09_in_vivo_dynamics.md:line 4Open reference8. D... -
4CitationIf astrocytes gate plasticity (Section {ref}
sec:plasticity), what are they actually doing during ongoing behaviour such that this gating can matter? The evidence compiled here frames an answer that departs substantially from the stimulus-specific picture carried over from acute-slice work (Section {ref}sec:calcium-signaling). In awake head-fixed rodents, astrocyte Ca$^{2+}$ is dominated by global arousal and loc...content/09_in_vivo_dynamics.md:line 4Open reference9 open- or closed-loop. These choices are not interchangeable: Lck-tethered indicators capture faster, smaller process events that cytosolic reporters underreport 5CitationIf astrocytes gate plasticity (Section {ref}sec:plasticity), what are they actually doing during ongoing behaviour such that this gating can matter? The evidence compiled here frames an answer that departs substantially from the stimulus-specific picture carried over from acute-slice work (Section {ref}sec:calcium-signaling). In awake head-fixed rodents, astrocyte Ca$^{2+}$ is dominated by global arousal and loc...content/09_in_vivo_dynamics.md:line 4Open reference0, and soma measurements bias towards long, coordinated transients that fine-process recordings fractionate into many distinct subcellular signals 5CitationIf astrocytes gate plasticity (Section {ref}sec:plasticity), what are they actually doing during ongoing behaviour such that this gating can matter? The evidence compiled here frames an answer that departs substantially from the stimulus-specific picture carried over from acute-slice work (Section {ref}sec:calcium-signaling). In awake head-fixed rodents, astrocyte Ca$^{2+}$ is dominated by global arousal and loc...content/09_in_vivo_dynamics.md:line 4Open reference1. D... -
5CitationIf astrocytes gate plasticity (Section {ref}
sec:plasticity), what are they actually doing during ongoing behaviour such that this gating can matter? The evidence compiled here frames an answer that departs substantially from the stimulus-specific picture carried over from acute-slice work (Section {ref}sec:calcium-signaling). In awake head-fixed rodents, astrocyte Ca$^{2+}$ is dominated by global arousal and loc...content/09_in_vivo_dynamics.md:line 4Open reference2 open- or closed-loop. These choices are not interchangeable: Lck-tethered indicators capture faster, smaller process events that cytosolic reporters underreport 5CitationIf astrocytes gate plasticity (Section {ref}sec:plasticity), what are they actually doing during ongoing behaviour such that this gating can matter? The evidence compiled here frames an answer that departs substantially from the stimulus-specific picture carried over from acute-slice work (Section {ref}sec:calcium-signaling). In awake head-fixed rodents, astrocyte Ca$^{2+}$ is dominated by global arousal and loc...content/09_in_vivo_dynamics.md:line 4Open reference3, and soma measurements bias towards long, coordinated transients that fine-process recordings fractionate into many distinct subcellular signals 5CitationIf astrocytes gate plasticity (Section {ref}sec:plasticity), what are they actually doing during ongoing behaviour such that this gating can matter? The evidence compiled here frames an answer that departs substantially from the stimulus-specific picture carried over from acute-slice work (Section {ref}sec:calcium-signaling). In awake head-fixed rodents, astrocyte Ca$^{2+}$ is dominated by global arousal and loc...content/09_in_vivo_dynamics.md:line 4Open reference4. D... -
5CitationIf astrocytes gate plasticity (Section {ref}
sec:plasticity), what are they actually doing during ongoing behaviour such that this gating can matter? The evidence compiled here frames an answer that departs substantially from the stimulus-specific picture carried over from acute-slice work (Section {ref}sec:calcium-signaling). In awake head-fixed rodents, astrocyte Ca$^{2+}$ is dominated by global arousal and loc...content/09_in_vivo_dynamics.md:line 4Open reference5 open- or closed-loop. These choices are not interchangeable: Lck-tethered indicators capture faster, smaller process events that cytosolic reporters underreport 5CitationIf astrocytes gate plasticity (Section {ref}sec:plasticity), what are they actually doing during ongoing behaviour such that this gating can matter? The evidence compiled here frames an answer that departs substantially from the stimulus-specific picture carried over from acute-slice work (Section {ref}sec:calcium-signaling). In awake head-fixed rodents, astrocyte Ca$^{2+}$ is dominated by global arousal and loc...content/09_in_vivo_dynamics.md:line 4Open reference6, and soma measurements bias towards long, coordinated transients that fine-process recordings fractionate into many distinct subcellular signals 5CitationIf astrocytes gate plasticity (Section {ref}sec:plasticity), what are they actually doing during ongoing behaviour such that this gating can matter? The evidence compiled here frames an answer that departs substantially from the stimulus-specific picture carried over from acute-slice work (Section {ref}sec:calcium-signaling). In awake head-fixed rodents, astrocyte Ca$^{2+}$ is dominated by global arousal and loc...content/09_in_vivo_dynamics.md:line 4Open reference7. D... -
5CitationIf astrocytes gate plasticity (Section {ref}
sec:plasticity), what are they actually doing during ongoing behaviour such that this gating can matter? The evidence compiled here frames an answer that departs substantially from the stimulus-specific picture carried over from acute-slice work (Section {ref}sec:calcium-signaling). In awake head-fixed rodents, astrocyte Ca$^{2+}$ is dominated by global arousal and loc...content/09_in_vivo_dynamics.md:line 4Open reference8 initiation point 5CitationIf astrocytes gate plasticity (Section {ref}sec:plasticity), what are they actually doing during ongoing behaviour such that this gating can matter? The evidence compiled here frames an answer that departs substantially from the stimulus-specific picture carried over from acute-slice work (Section {ref}sec:calcium-signaling). In awake head-fixed rodents, astrocyte Ca$^{2+}$ is dominated by global arousal and loc...content/09_in_vivo_dynamics.md:line 4Open reference9. -
6Citationobjective [dombeck2007neuron], and this preparation has since been populated by genetically encoded indicators driven from astrocytecontent/09_in_vivo_dynamics.md:line 12Open reference0 n,=,31 and 30 respectively) 6Citationobjective [dombeck2007neuron], and this preparation has since been populated by genetically encoded indicators driven from astrocytecontent/09_in_vivo_dynamics.md:line 12Open reference1, and the
-
6Citationobjective [dombeck2007neuron], and this preparation has since been populated by genetically encoded indicators driven from astrocytecontent/09_in_vivo_dynamics.md:line 12Open reference2 kinetics 6Citationobjective [dombeck2007neuron], and this preparation has since been populated by genetically encoded indicators driven from astrocytecontent/09_in_vivo_dynamics.md:line 12Open reference3.
-
6Citationobjective [dombeck2007neuron], and this preparation has since been populated by genetically encoded indicators driven from astrocytecontent/09_in_vivo_dynamics.md:line 12Open reference4 kinetics 6Citationobjective [dombeck2007neuron], and this preparation has since been populated by genetically encoded indicators driven from astrocytecontent/09_in_vivo_dynamics.md:line 12Open reference5.
-
6Citationobjective [dombeck2007neuron], and this preparation has since been populated by genetically encoded indicators driven from astrocytecontent/09_in_vivo_dynamics.md:line 12Open reference6 kinetics 6Citationobjective [dombeck2007neuron], and this preparation has since been populated by genetically encoded indicators driven from astrocytecontent/09_in_vivo_dynamics.md:line 12Open reference7.
-
6Citationobjective [dombeck2007neuron], and this preparation has since been populated by genetically encoded indicators driven from astrocytecontent/09_in_vivo_dynamics.md:line 12Open reference8 itself 6Citationobjective [dombeck2007neuron], and this preparation has since been populated by genetically encoded indicators driven from astrocytecontent/09_in_vivo_dynamics.md:line 12Open reference9,
-
6Citationobjective [dombeck2007neuron], and this preparation has since been populated by genetically encoded indicators driven from astrocytecontent/09_in_vivo_dynamics.md:line 12Open reference0 itself 6Citationobjective [dombeck2007neuron], and this preparation has since been populated by genetically encoded indicators driven from astrocytecontent/09_in_vivo_dynamics.md:line 12Open reference1,
-
6Citationobjective [dombeck2007neuron], and this preparation has since been populated by genetically encoded indicators driven from astrocytecontent/09_in_vivo_dynamics.md:line 12Open reference2 itself 6Citationobjective [dombeck2007neuron], and this preparation has since been populated by genetically encoded indicators driven from astrocytecontent/09_in_vivo_dynamics.md:line 12Open reference3,
-
6Citationobjective [dombeck2007neuron], and this preparation has since been populated by genetically encoded indicators driven from astrocytecontent/09_in_vivo_dynamics.md:line 12Open reference4 itself 6Citationobjective [dombeck2007neuron], and this preparation has since been populated by genetically encoded indicators driven from astrocytecontent/09_in_vivo_dynamics.md:line 12Open reference5,
-
6Citationobjective [dombeck2007neuron], and this preparation has since been populated by genetically encoded indicators driven from astrocytecontent/09_in_vivo_dynamics.md:line 12Open reference6 itself 6Citationobjective [dombeck2007neuron], and this preparation has since been populated by genetically encoded indicators driven from astrocytecontent/09_in_vivo_dynamics.md:line 12Open reference7,
-
6Citationobjective [dombeck2007neuron], and this preparation has since been populated by genetically encoded indicators driven from astrocytecontent/09_in_vivo_dynamics.md:line 12Open reference8 cerebellum 6Citationobjective [dombeck2007neuron], and this preparation has since been populated by genetically encoded indicators driven from astrocytecontent/09_in_vivo_dynamics.md:line 12Open reference9.
-
7Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference0 cerebellum 7Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference1.
-
7Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference2 cerebellum 7Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference3.
-
7Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference4 cerebellum 7Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference5.
-
7Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference6 parameters do 7Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference7.
-
7Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference8 parameters do 7Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference9.
-
7Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference, 8Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference, 9Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference, 10Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference, 11Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference, 12Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference0 parameters do 7Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference, 8Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference, 9Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference, 10Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference, 11Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference, 12Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference1.
-
7Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference, 8Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference, 9Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference, 10Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference, 11Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference, 12Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference2 mice) 7Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference, 8Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference, 9Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference, 10Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference, 11Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference, 12Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference3. The authors attributed this to the
-
7Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference, 8Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference, 9Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference, 10Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference, 11Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference, 12Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference4 (270.7,±,4.3,ms) 7Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference, 8Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference, 9Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference, 10Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference, 11Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference, 12Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference5. The conflict is
-
7Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference, 8Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference, 9Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference, 10Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference, 11Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference, 12Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference6 experiment is designed to detect 7Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference, 8Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference, 9Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference, 10Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference, 11Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference, 12Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference7.
-
7Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference, 8Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference, 9Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference, 10Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference, 11Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference, 12Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference8 experiment is designed to detect 7Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference, 8Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference, 9Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference, 10Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference, 11Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference, 12Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference9.
-
8Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference0 experiment is designed to detect 8Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference1.
-
8Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference2 experiment is designed to detect 8Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference3.
-
8Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference4 experiment is designed to detect 8Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference5.
-
8Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference6 quiet-wake controls 8Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference7.
-
8Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference8 quiet-wake controls 8Citationkinetics [mukamel2009neuron,srinivasan2016neuron,jiang2014jove,weiss2025jneurosci,cooke2025eneuro,fuhrmann2025communbiol]content/09_in_vivo_dynamics.md:line 14Open reference9.
-
2CitationIf astrocytes gate plasticity (Section {ref}
sec:plasticity), what are they actually doing during ongoing behaviour such that this gating can matter? The evidence compiled here frames an answer that departs substantially from the stimulus-specific picture carried over from acute-slice work (Section {ref}sec:calcium-signaling). In awake head-fixed rodents, astrocyte Ca$^{2+}$ is dominated by global arousal and loc...content/09_in_vivo_dynamics.md:line 4Open reference00 quiet-wake controls 2CitationIf astrocytes gate plasticity (Section {ref}sec:plasticity), what are they actually doing during ongoing behaviour such that this gating can matter? The evidence compiled here frames an answer that departs substantially from the stimulus-specific picture carried over from acute-slice work (Section {ref}sec:calcium-signaling). In awake head-fixed rodents, astrocyte Ca$^{2+}$ is dominated by global arousal and loc...content/09_in_vivo_dynamics.md:line 4Open reference01. -
... 70 additional anchors in refs_json
References
- [paukert_2014_neuron] “If astrocytes gate plasticity (Section {ref}`sec:plasticity`), what are they actually doing during ongoing behaviour such that this gating can matter? The evidence compiled here frames an answer that departs substantially from the stimulus-specific picture carried over from acute-slice work (Section {ref}`sec:calcium-signaling`). In awake head-fixed rodents, astrocyte Ca$^{2+}$ is dominated by global arousal and loc...”
- [ye_2020_natcommun] “If astrocytes gate plasticity (Section {ref}`sec:plasticity`), what are they actually doing during ongoing behaviour such that this gating can matter? The evidence compiled here frames an answer that departs substantially from the stimulus-specific picture carried over from acute-slice work (Section {ref}`sec:calcium-signaling`). In awake head-fixed rodents, astrocyte Ca$^{2+}$ is dominated by global arousal and loc...”
- [reimer_2016_natcommun] “If astrocytes gate plasticity (Section {ref}`sec:plasticity`), what are they actually doing during ongoing behaviour such that this gating can matter? The evidence compiled here frames an answer that departs substantially from the stimulus-specific picture carried over from acute-slice work (Section {ref}`sec:calcium-signaling`). In awake head-fixed rodents, astrocyte Ca$^{2+}$ is dominated by global arousal and loc...”
- [reitman_2023_natneurosci] “If astrocytes gate plasticity (Section {ref}`sec:plasticity`), what are they actually doing during ongoing behaviour such that this gating can matter? The evidence compiled here frames an answer that departs substantially from the stimulus-specific picture carried over from acute-slice work (Section {ref}`sec:calcium-signaling`). In awake head-fixed rodents, astrocyte Ca$^{2+}$ is dominated by global arousal and loc...”
- [stobart_2018_neuron] “If astrocytes gate plasticity (Section {ref}`sec:plasticity`), what are they actually doing during ongoing behaviour such that this gating can matter? The evidence compiled here frames an answer that departs substantially from the stimulus-specific picture carried over from acute-slice work (Section {ref}`sec:calcium-signaling`). In awake head-fixed rodents, astrocyte Ca$^{2+}$ is dominated by global arousal and loc...”
- [dombeck_2007_neuron] “objective [dombeck_2007_neuron], and this preparation has since been populated by genetically encoded indicators driven from astrocyte”
- [mukamel_2009_neuron] “kinetics [mukamel_2009_neuron,srinivasan_2016_neuron,jiang_2014_jove,weiss_2025_jneurosci,cooke_2025_eneuro,fuhrmann_2025_communbiol]”
- [srinivasan_2016_neuron] “kinetics [mukamel_2009_neuron,srinivasan_2016_neuron,jiang_2014_jove,weiss_2025_jneurosci,cooke_2025_eneuro,fuhrmann_2025_communbiol]”
- [jiang_2014_jove] “kinetics [mukamel_2009_neuron,srinivasan_2016_neuron,jiang_2014_jove,weiss_2025_jneurosci,cooke_2025_eneuro,fuhrmann_2025_communbiol]”
- [weiss_2025_jneurosci] “kinetics [mukamel_2009_neuron,srinivasan_2016_neuron,jiang_2014_jove,weiss_2025_jneurosci,cooke_2025_eneuro,fuhrmann_2025_communbiol]”
- [cooke_2025_eneuro] “kinetics [mukamel_2009_neuron,srinivasan_2016_neuron,jiang_2014_jove,weiss_2025_jneurosci,cooke_2025_eneuro,fuhrmann_2025_communbiol]”
- [fuhrmann_2025_communbiol] “kinetics [mukamel_2009_neuron,srinivasan_2016_neuron,jiang_2014_jove,weiss_2025_jneurosci,cooke_2025_eneuro,fuhrmann_2025_communbiol]”
- [gau_2024_natcommun] “licking [reimer_2016_natcommun,reitman_2023_natneurosci,gau_2024_natcommun].”
- [bojarskaite_2020_natcommun] “open- or closed-loop. These choices are not interchangeable: Lck-tethered indicators capture faster, smaller process events that cytosolic reporters underreport [bojarskaite_2020_natcommun,umpierre_2020_elife], and soma measurements bias towards long, coordinated transients that fine-process recordings fractionate into many distinct subcellular signals [bindocci_2017_science,rungta_2016_glia,lia_2025_bioprotocol]. D...”
- [umpierre_2020_elife] “open- or closed-loop. These choices are not interchangeable: Lck-tethered indicators capture faster, smaller process events that cytosolic reporters underreport [bojarskaite_2020_natcommun,umpierre_2020_elife], and soma measurements bias towards long, coordinated transients that fine-process recordings fractionate into many distinct subcellular signals [bindocci_2017_science,rungta_2016_glia,lia_2025_bioprotocol]. D...”
- [bindocci_2017_science] “open- or closed-loop. These choices are not interchangeable: Lck-tethered indicators capture faster, smaller process events that cytosolic reporters underreport [bojarskaite_2020_natcommun,umpierre_2020_elife], and soma measurements bias towards long, coordinated transients that fine-process recordings fractionate into many distinct subcellular signals [bindocci_2017_science,rungta_2016_glia,lia_2025_bioprotocol]. D...”
- [rungta_2016_glia] “open- or closed-loop. These choices are not interchangeable: Lck-tethered indicators capture faster, smaller process events that cytosolic reporters underreport [bojarskaite_2020_natcommun,umpierre_2020_elife], and soma measurements bias towards long, coordinated transients that fine-process recordings fractionate into many distinct subcellular signals [bindocci_2017_science,rungta_2016_glia,lia_2025_bioprotocol]. D...”
- [lia_2025_bioprotocol] “open- or closed-loop. These choices are not interchangeable: Lck-tethered indicators capture faster, smaller process events that cytosolic reporters underreport [bojarskaite_2020_natcommun,umpierre_2020_elife], and soma measurements bias towards long, coordinated transients that fine-process recordings fractionate into many distinct subcellular signals [bindocci_2017_science,rungta_2016_glia,lia_2025_bioprotocol]. D...”
- [stobart_2018_cerebral] “open- or closed-loop. These choices are not interchangeable: Lck-tethered indicators capture faster, smaller process events that cytosolic reporters underreport [bojarskaite_2020_natcommun,umpierre_2020_elife], and soma measurements bias towards long, coordinated transients that fine-process recordings fractionate into many distinct subcellular signals [bindocci_2017_science,rungta_2016_glia,lia_2025_bioprotocol]. D...”
- [wang_2024_neurophoton] “open- or closed-loop. These choices are not interchangeable: Lck-tethered indicators capture faster, smaller process events that cytosolic reporters underreport [bojarskaite_2020_natcommun,umpierre_2020_elife], and soma measurements bias towards long, coordinated transients that fine-process recordings fractionate into many distinct subcellular signals [bindocci_2017_science,rungta_2016_glia,lia_2025_bioprotocol]. D...”
- [nimmerjahn_2009_neuron] “initiation point [nimmerjahn_2009_neuron].”
- [salinasbirt_2023_glia] “kinetics [paukert_2014_neuron,salinasbirt_2023_glia,heo_2025_iscience].”
- [heo_2025_iscience] “kinetics [paukert_2014_neuron,salinasbirt_2023_glia,heo_2025_iscience].”
- [monai_2021_scirep] “itself [paukert_2014_neuron,ye_2020_natcommun,salinasbirt_2023_glia,monai_2021_scirep,heo_2025_iscience],”
- [pittolo_2022_unknown] “cerebellum [ye_2020_natcommun,pittolo_2022_unknown,heo_2025_iscience,wahis_2023_unknown].”
- [wahis_2023_unknown] “cerebellum [ye_2020_natcommun,pittolo_2022_unknown,heo_2025_iscience,wahis_2023_unknown].”
- [rupprecht_2024_natneurosci] “parameters do [reitman_2023_natneurosci,gau_2024_natcommun,rupprecht_2024_natneurosci].”
- [bjrnstad_2021_frontcell] “experiment is designed to detect [stobart_2018_neuron,stobart_2018_cerebral,rungta_2016_glia,bindocci_2017_science,bjrnstad_2021_frontcell].”
Sister wikis (recently updated · no domain on this page)
- Agent Recipe: AI-for-Biology Closed-Loop with Reviewer Handoffs and Eval Contracts
- Agent Recipe: AI-for-Biology Closed-Loop with Reviewer Handoffs and Eval Contracts
- test
- JGBO-I27: Top 10 GBO Questions for Prioritization
- JGBO-I27: Top 10 GBO Questions for Prioritization
- Design Brief: Beta-test Evaluation Protocol for SciDEX v2 Design Trajectories
- Andy — Showcase Findings (auto-curated)
- Kris — Showcase Findings (auto-curated)
Recent activity here
No recent events touching this page.