Network physiology Synchronization and global synchronization phenomena play essential role in the field of Network Physiology which focuses on whole-body research to understand the mechanisms through which physiological systems and sub-systems — from sub-cellular, metabolic and genomic scale to cellular and neuronal networks, to organs and the organism level — synchronize their dynamics to coordinate functions and generate distinct physiological states in health and disease. Amplitude, frequency, and phase synchronization, as forms of coupling and interaction, underlie biological and physiological network mechanisms through which global states, functions and behaviors emerge at the system and organism level. Synchronization has been reported across physiological systems and levels of integration, including cardio-respiratory coupling; maternal-fetal cardiac phase-synchronization; brain blood flow velocity vs. peripheral blood pressure in stroke; synchronization in neuron synaptic function; organ networks; EEG-synchronization and EEG-desynchronization in NREM and REM sleep; brain waves synchronization and anti-synchronization during rest, exercise, cognitive tasks, sleep and wake; cortico-muscular synchronization; synchronization in pancreatic cells and metabolism; inter-muscular muscle fibers synchronization in exercise and fatigue; neuromodulation and Parkinson's, dystonia and epilepsy; circadian synchrony of sleep, nutrition and physical activity.
Neuroscience In cognitive neuroscience, (stimulus-dependent) (phase-)synchronous oscillations of neuron populations serve to solve the general
binding problem. According to the so-called Binding-By-Synchrony (BBS) Hypothesis a precise temporal correlation between the impulses of neurons ("cross-correlation analysis") and thus a stimulus-dependent temporal synchronization of the coherent activity of subpopulations of neurons emerges. Moreover, this synchronization mechanism circumvents the
superposition problem by more effectively identifying the signature of synchronous neuronal signals as belonging together for subsequent (sub-)cortical information processing areas.
Cognitive science In cognitive science, integrative (phase) synchronization mechanisms in cognitive neuroarchitectures of modern
connectionism that include coupled oscillators (e.g."Oscillatory Networks") are used to solve the
binding problem of cognitive neuroscience in perceptual cognition ("feature binding") and in language cognition ("variable binding").
Biological networks There is a concept that the synchronization of biochemical reactions determines biological
homeostasis. According to this theory, all reactions occurring in a living cell are synchronized in terms of quantities and timescales to maintain
biological network functional. == Human movement ==