Episodic Memory formation: A review of complex Hippocampus input pathways.

Memories of everyday experiences involve the encoding of a rich and dynamic representation of present objects and their contextual features. Traditionally, the resulting mnemonic trace is referred to as Episodic Memory, i.e. the "what", "where" and "when" of a lived episode. The journey for such memory trace encoding begins with the perceptual data of an experienced episode handled in sensory brain regions. The information is then streamed to cortical areas located in the ventral Medio Temporal Lobe, which produces multi-modal representations concerning either the objects (in the Perirhinal cortex) or the spatial and contextual features (in the parahippocampal region) of the episode. Then, this high-level data is gated through the Entorhinal Cortex and forwarded to the Hippocampal Formation, where all the pieces get bound together. Eventually, the resulting encoded neural pattern is relayed back to the Neocortex for a stable consolidation. This review will detail these different stages and provide a systematic overview of the major cortical streams toward the Hippocampus relevant for Episodic Memory encoding.

Anatomical asymmetries in the tectofugal pathway of dark-incubated domestic chicks: Rightwards lateralization of parvalbumin neurons in the entopallium.

The discovery of the role of light exposure for the development of lateralization in domestic chick embryos revolutionized this research field. However, two main issues remain unresolved: (i) while in chicks anatomical light-dependent lateralization is mostly confined to the thalamofugal visual pathway, in pigeons only the tectofugal pathway is lateralized after light exposure. However, no study in either species ever investigated anatomical lateralization in the entopallium, the forebrain station of the tectofugal pathway. (ii) It is now known that lateralization can be observed also in dark-incubated chicks, both at the behavioural and at the Immediate Early Gene-expression level. We hypothesized that lateralization of the tectofugal system may underlie these light-independent effects. To investigate structural lateralization in the tectofugal pathway of dark-incubated chicks, we used parvalbumin (PV) as a marker of a sub population of entopallial neurons, quantifying PV-ir cell densities in the left and right entopallium. We found higher density in the right hemisphere, revealing for the first time anatomical lateralization in entopallium and confirming its potential role in supporting lateralized brain processing in dark-incubated birds. Results are discussed in relation to the possible functional role of PV-ir cells in inhibitory neural functions.