Even when the primary visual cortical area is absent bilaterally from early life, the rest of a primate visual brain can develop and function normally to support day-to-day visual behaviour.

Polarized light imaging demonstrates detailed organization of projection, callosal, longitudinal association and short association fibers in the primate visual system at micrometer-resolution.

The primate caudal area 47/12 is anatomically and functionally connected with the main nodes of the salience network, supporting the role of the ventrolateral prefrontal cortex in all major attention networks.

In vivo quantitative magnetic resonance imaging at ultra-high magnetic field reveals systematic differences of relaxation parameters (R₁) within the human secondary visual cortex at the level of the thin-thick-pale stripes system, which points toward higher cortical myelination of pale stripes.

Primate attention is not limited to a dorsal fronto-parietal network, but includes a ventral temporal node and its dorso-ventral interactions with other attentional areas.

Using Monkey EEG as a bridge technology, color and motion representations in human MEG are linked to microcircuit activity in ventral stream areas.

Light and X-ray scattering on the same primate and human brain samples cross-validate each other and enable accurate mapping of axonal trajectories in regions with uni- and multi-directional nerve fibers, which can be used to validate diffusion MRI.

A distinct cortical region serves head gaze following, and is needed to establish joint attention with others and to ultimately develop a theory of others' mind.

A hub in the rostral anterior cingulate cortex receives unusually high and functionally diverse inputs, providing a biological interface between motivation, incentive based learning, and decision making.

Shared traits in gaze patterns and brain activations between marmosets and humans during Theory of Mind animations reveal cross-species cognitive similarities.