The Superior Colliculus/Lateral Posterior Thalamic Nuclei in Mice Rapidly Transmit Fear Visual Information Through the Theta Frequency Band

“…Relative to their location, the reduction in f is was most prominent in posterior subregions, particularly the lateral posterior subregions, which act in concert with the pulvinar subregions as key components of the visual pathway. 36 The lower f is observed in subregions located close to the ventricles supports the “ependymal‐in” gradient concept of thalamic damage in MS, 37 analogous to the “pial‐in” cortical gradient demonstrated for cortical damage. 18 , 19 , 38 , 39 Subependymal neuroaxonal loss has been associated with the presence of subependymal perivascular B‐cell infiltrates and soluble inflammatory factors in the cerebrospinal fluid, damaging thalamic tissue directly or indirectly by microglia activation.…”

“…Interestingly, atrophy‐prone thalamic subregions showed higher f ec and lower f is , reflecting an increased extra‐cellular space and greater cell body loss. Relative to their location, the reduction in f is was most prominent in posterior subregions, particularly the lateral posterior subregions, which act in concert with the pulvinar subregions as key components of the visual pathway 36 . The lower f is observed in subregions located close to the ventricles supports the “ependymal‐in” gradient concept of thalamic damage in MS, 37 analogous to the “pial‐in” cortical gradient demonstrated for cortical damage 18,19,38,39 .…”

Intrinsic and extrinsic contributors to subregional thalamic volume loss in multiple sclerosis

“…Relative to their location, the reduction in f is was most prominent in posterior subregions, particularly the lateral posterior subregions, which act in concert with the pulvinar subregions as key components of the visual pathway. 36 The lower f is observed in subregions located close to the ventricles supports the “ependymal‐in” gradient concept of thalamic damage in MS, 37 analogous to the “pial‐in” cortical gradient demonstrated for cortical damage. 18 , 19 , 38 , 39 Subependymal neuroaxonal loss has been associated with the presence of subependymal perivascular B‐cell infiltrates and soluble inflammatory factors in the cerebrospinal fluid, damaging thalamic tissue directly or indirectly by microglia activation.…”

“…Interestingly, atrophy‐prone thalamic subregions showed higher f ec and lower f is , reflecting an increased extra‐cellular space and greater cell body loss. Relative to their location, the reduction in f is was most prominent in posterior subregions, particularly the lateral posterior subregions, which act in concert with the pulvinar subregions as key components of the visual pathway 36 . The lower f is observed in subregions located close to the ventricles supports the “ependymal‐in” gradient concept of thalamic damage in MS, 37 analogous to the “pial‐in” cortical gradient demonstrated for cortical damage 18,19,38,39 .…”

Intrinsic and extrinsic contributors to subregional thalamic volume loss in multiple sclerosis

“…Two small trepanations (diameter: 2 mm) were drilled over the cerebellum and the olfactory bulb to place silver ball electrodes on top of the dura used to ground (olfactory bulb) the animal and to provide the reference signals for local field potentials (cerebellum). A 16‐channel (4 × 4) microelectrode array (length: 5 mm, pitch: 200 μm, Hong Kong Plexon Inc.) 30 was inserted through the dura mater into the dPAG nuclei (anterior–posterior: −3.88 mm; medial–lateral: +0.38 mm; dorsal–ventral: −2.3 mm) according to The Mouse Brain in Stereotaxic Coordinates (third edition) at an angle perpendicular to the cortical surface. A slight dimpling of up to 100 μm of the cortex was accepted.…”

Different coding characteristics between flight and freezing in dorsal periaqueductal gray of mice during exposure to innate threats

GABAergic Retinal Ganglion Cells Projecting to the Superior Colliculus Mediate the Looming-Evoked Flight Response