To ensure smooth sequential actions, reaches to at least two future targets are planned during the execution of the current reach and the planning processes of the future reaches interact.

When carrying out a sequence of movements, humans can plan several steps in advance to make the movement smooth.

The neuroanatomical and functional analysis of genetically-identified motoneurons controlling all major steps of Drosophila proboscis extension provides new insights into the architecture of a motor circuitry controlling a reaching-like behavior.

Inhibition of protein synthesis in primary motor cortex (M1) of monkeys disrupted the performance of skilled sequential movements suggesting that M1 is involved in maintenance of skilled sequential movements.

The rhythmic patterns of activity that underlie breathing are generated and coordinated by distinct populations of neurons within the brainstem.

Using a sequential neurofeedback-arm reaching task, a new link is established among population neural activity patterns, generation of beta oscillations, and motor behavior changes.

Long-latency reflexes flexibly encode future goals during sequential reaching movements, reflecting the parallel and task-dependent processing of a sequence of goals in circuits that mediate fast feedback control.

The postinspiratory complex acts as an interface between the swallow pattern generator and the preBötzinger complex to coordinate swallow and breathing.

A synthetic quadrastable gene network provides a synthetic biology framework to study cell fate determination.

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.