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

The connectivity structure of a nociceptive circuit is precisely maintained over Drosophila larval development through cell type-specific increases in synaptic contacts as measured from electron microscopy reconstructions, while individual neurons grow five-fold in size and number of synapses.

Openly available structural imaging processing pipeline for chimpanzees including registration templates and macro-anatomical parcellation shows human-like cerebral aging and medial hemispheric organization.

FlyBrainLab is an open-source computing platform that integrates 3D exploration and visualization of diverse Drosophila connectomic/synaptomic datasets with interactive exploration of the functional logic of modeled executable brain circuits.

A combination of genetic, anatomical and physiological techniques has revealed that the lateral horn, a region of the brain involved in olfaction in flies, has many more types of neurons than expected.

An optimal wire and function trade-off emerges from noisy growth and stochastic retraction during Drosophila class I ventral posterior dendritic arborisation (c1vpda) dendrite development.

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.

Serial-section electron microscopy uncovers the intricate neural network of the bumblebee central complex, revealing highly conserved projection patterns as well as novel circuit elements potentially unique to bees.

Fetal Zika virus’ direct infection of the brain causes neuroanatomical pathology that tracks with the brain development, following a caudal-to-rostral trajectory, even in individuals who do not develop microcephaly.