Macaque monkeys temporally compress past experiences and use a forward-replay mechanism during judgment of temporal-order between episodes.

Individuals with reversed congenital cataracts perceived visual events as occurring earlier than auditory and tactile events revealing that cross-modal temporal biases depend on sensory experience during an early sensitive period.

The transition from a restrictive patterning mechanism to one sensitive to a variety of environmental cues in NOTCH-mediated angiogenesis offers crucial insights into vascularization in damaged organs and cancer therapy.

Through mathematical analysis and computer simulations, the neuronal underpinnings of feasible models of sequence learning are delineated.

The human brain involuntarily exploits multiscale regularities in rhythmic contexts to recompose the dynamic profile of visual temporal attention.

Temporally delayed linear modelling provides a domain-general linear framework for sequence detection and statistical testing, and is able to detect replays in both human neuroimaging and animal electrophysiology.

Mice and humans learned to distinguish an arbitrary tactile sequence from other stimuli that differed only in their temporal patterning over hundreds of milliseconds, showing that sequence learning generalises across sensory modalities.

The aged human auditory cortex shows preserved tonotopy, but temporal modulations are represented with a markedly broader tuning, highlighting decreased temporal selectivity as a hallmark of the aging auditory cortex.

In triple-drug-treated HIV, partially resistant viruses can spread and resistance to specific drugs evolves in a predictable order, potentially a result of spatial or temporal heterogeneity in drug concentrations.

A newly identified pattern of circuit assembly shows connectivity between small groups of neurons born in tight time windows from different stem cells, with outputs from one lineage born before inputs from other lineages.