sub-MS21_sessions.tsv 5.7 KB

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  1. session_id #_trials comment
  2. ses-PeterMS21180621141817 125 Petersen et al. demonstrate that cooling of the medial septum slows theta oscillation and increases choice errors without affecting spatial features of pyramidal neurons. Cooling affects distance-time, but not distance-theta phase, compression. The findings reveal that cell assemblies are organized by theta phase and not by external (clock) time.
  3. ses-PeterMS21180622174411 131 Petersen et al. demonstrate that cooling of the medial septum slows theta oscillation and increases choice errors without affecting spatial features of pyramidal neurons. Cooling affects distance-time, but not distance-theta phase, compression. The findings reveal that cell assemblies are organized by theta phase and not by external (clock) time.
  4. ses-PeterMS21180623170717concat 122 Petersen et al. demonstrate that cooling of the medial septum slows theta oscillation and increases choice errors without affecting spatial features of pyramidal neurons. Cooling affects distance-time, but not distance-theta phase, compression. The findings reveal that cell assemblies are organized by theta phase and not by external (clock) time.
  5. ses-PeterMS21180625153927concat 128 Petersen et al. demonstrate that cooling of the medial septum slows theta oscillation and increases choice errors without affecting spatial features of pyramidal neurons. Cooling affects distance-time, but not distance-theta phase, compression. The findings reveal that cell assemblies are organized by theta phase and not by external (clock) time.
  6. ses-PeterMS21180627143449concat 179 Petersen et al. demonstrate that cooling of the medial septum slows theta oscillation and increases choice errors without affecting spatial features of pyramidal neurons. Cooling affects distance-time, but not distance-theta phase, compression. The findings reveal that cell assemblies are organized by theta phase and not by external (clock) time.
  7. ses-PeterMS21180628155921concat 168 Petersen et al. demonstrate that cooling of the medial septum slows theta oscillation and increases choice errors without affecting spatial features of pyramidal neurons. Cooling affects distance-time, but not distance-theta phase, compression. The findings reveal that cell assemblies are organized by theta phase and not by external (clock) time.
  8. ses-PeterMS21180629110332concat 169 Petersen et al. demonstrate that cooling of the medial septum slows theta oscillation and increases choice errors without affecting spatial features of pyramidal neurons. Cooling affects distance-time, but not distance-theta phase, compression. The findings reveal that cell assemblies are organized by theta phase and not by external (clock) time.
  9. ses-PeterMS21180711112927concat 129 Petersen et al. demonstrate that cooling of the medial septum slows theta oscillation and increases choice errors without affecting spatial features of pyramidal neurons. Cooling affects distance-time, but not distance-theta phase, compression. The findings reveal that cell assemblies are organized by theta phase and not by external (clock) time.
  10. ses-PeterMS21180712103200concat 127 Petersen et al. demonstrate that cooling of the medial septum slows theta oscillation and increases choice errors without affecting spatial features of pyramidal neurons. Cooling affects distance-time, but not distance-theta phase, compression. The findings reveal that cell assemblies are organized by theta phase and not by external (clock) time.
  11. ses-PeterMS21180719155941concat 132 Petersen et al. demonstrate that cooling of the medial septum slows theta oscillation and increases choice errors without affecting spatial features of pyramidal neurons. Cooling affects distance-time, but not distance-theta phase, compression. The findings reveal that cell assemblies are organized by theta phase and not by external (clock) time.
  12. ses-PeterMS21180720110037concat 187 Petersen et al. demonstrate that cooling of the medial septum slows theta oscillation and increases choice errors without affecting spatial features of pyramidal neurons. Cooling affects distance-time, but not distance-theta phase, compression. The findings reveal that cell assemblies are organized by theta phase and not by external (clock) time.
  13. ses-PeterMS21180724144402concat 192 Petersen et al. demonstrate that cooling of the medial septum slows theta oscillation and increases choice errors without affecting spatial features of pyramidal neurons. Cooling affects distance-time, but not distance-theta phase, compression. The findings reveal that cell assemblies are organized by theta phase and not by external (clock) time.
  14. ses-PeterMS21180730120605concat 138 Petersen et al. demonstrate that cooling of the medial septum slows theta oscillation and increases choice errors without affecting spatial features of pyramidal neurons. Cooling affects distance-time, but not distance-theta phase, compression. The findings reveal that cell assemblies are organized by theta phase and not by external (clock) time.
  15. ses-PeterMS21180802120147concat 152 Petersen et al. demonstrate that cooling of the medial septum slows theta oscillation and increases choice errors without affecting spatial features of pyramidal neurons. Cooling affects distance-time, but not distance-theta phase, compression. The findings reveal that cell assemblies are organized by theta phase and not by external (clock) time.
  16. ses-PeterMS21180803142301concat 121 Petersen et al. demonstrate that cooling of the medial septum slows theta oscillation and increases choice errors without affecting spatial features of pyramidal neurons. Cooling affects distance-time, but not distance-theta phase, compression. The findings reveal that cell assemblies are organized by theta phase and not by external (clock) time.