The large patches at the dorsal border of medial entorhinal cortex, however, seem to not have been fully identified NSC 683864 price in previous studies (Witter and Amaral, 2004 and Boccara et al., 2010). Since the medial and dorsal large patches are continuous and cytoarchitectonically similar, we consider them to be one—putatively parasubicular—structure and refer to them as large patches. Often but not
always the large patches could be divided in two vertically split subpatches (Figures 2A and 2B). Quantification of cytochrome oxidase activity levels revealed a clear periodicity of patches (Figures S2A and S2B), which were visible along the entire mediolateral extent of medial entorhinal cortex (Figures S2C–S2E). To further characterize the organization of medial entorhinal cortex, we stained alternating parasagittal, horizontal, or tangential sections for cytochrome oxidase activity, Nissl, and myelin. Differences in cell size, density, soma morphology, and cytochrome oxidase activity confirmed the existence of the two types of patches (Figures 2A–2C). Areas of higher cell density in layer 2, as visualized by Nissl staining, coincided with the patches identified by cytochrome oxidase activity staining (Figure 2C), and the patchy organization was typically
more obvious in cytochrome oxidase than in Nissl stains. Large patches showed strong cytochrome oxidase reactivity, probably reflecting
a constitutively high metabolic activity. They differed strikingly from the surrounding cortical sheet and distorted the cortical lamination (Figure 2D). Fasudil cell line Their broad PTPRJ dorsal part extended into layer 1, and their ventral part tapered out toward layer 4. Many myelinated axons originated from these patches, but myelination did not extend into their broad dorsal part (Figure 2E). The small layer 2 patches were also often surrounded by myelinated fibers (data not shown). The architecture of small patches changed along the dorsoventral axis: cell size and myelination decreased (data not shown), while patch size increased (Figure 2F; Figure S3). Cells in large patches appeared to be smaller than adjacent neurons in small layer 2 patches (Figure 2D) and had a unique dendritic morphology, strongly polarized away from the patch border (Figure 2G). Within layer 2 the dendrites of layer 2 stellate cells were also largely but not exclusively restricted to their home patch, while they extended more broadly in layer 1 (Figure 2G; Figure S4). Interestingly, patch diameters seemed to be within the range of the deep-to-superficial “input clusters” widths reported by Beed et al. (2010) for stellate cells (∼200 μm at midlevel of medial entorhinal cortex), suggesting a possible correlation between patches and interlaminar inputs in medial entorhinal cortex.