Emotional learning retroactively promotes memory integration for previously neutral events into episodic memory to foster future event predictions, through rapidly stimulating trial-specific reactivation of overlapping memory traces and reorganization of associated memories among the amygdala, hippocampal, and neocortical circuits.

Neuroimaging proves to be a powerful tool for capturing spatial and temporal dynamics across the whole nonhuman primate brain, bridging the gap between human and animal models.

Naturalistic animal behavior exhibits a complex organization in the temporal domain, whose variability stems from hierarchical, contextual, and stochastic sources and can be naturally explained in terms of metastable attractor models.

In juvenile songbirds, neural sequences pre-exist tutor exposure, and the process of learning a new song may make use of existing neural sequences as a stable substrate for new behavioral changes.

The brain continues to represent individual fingers in primary somatosensory cortex decades after the amputation of a hand, indicating that cortical maps do not require ongoing sensory input from the body.

Retinal pigment epithelium flattening is an efficient solution adopted by the fast-developing zebrafish to enable folding of the eye primordia, which contrasts with the proliferation-based mechanism used by amniotes.

Anterior Cingulate Cortex displays robust tracking during strategy execution of a summary statistic for that strategy in recent behavioral history, suggesting a role for this brain region in estimating which actions promote the occurrence of events in the environment.

The spatial dimension of neural activity is an organizing feature of the neural code that controls motor actions.

Inter-species variations in connectome architecture across the mammalian phylogenetic spectrum recapitulate established taxonomic relationships defined by genetic, morphology, and behavioural differences, and are mainly driven by local changes in connectivity while hallmark global features tend to be conserved across species.

Fish-derived pluripotent cells instinctively form retinal tissue recapitulating key steps of early eye development.