session_id	#_trials	comment
ses-PeterMS22180621131028	115	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.
ses-PeterMS22180622115734concat	80	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.
ses-PeterMS22180623170141concat	113	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.
ses-PeterMS22180625162932concat	116	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.
ses-PeterMS22180626110916concat	134	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.
ses-PeterMS22180627114856concat	162	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.
ses-PeterMS22180628120341concat	159	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.
ses-PeterMS22180629110319concat	143	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.
ses-PeterMS22180711112912concat	111	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.
ses-PeterMS22180712102504concat	151	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.
ses-PeterMS22180719122813concat	142	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.
ses-PeterMS22180720110055concat	141	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.
ses-PeterMS22180724144421concat	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.