The establishment of the concept of brainwave entrainment is based on several key insights. A relationship between neural activity and external stimuli has been a subject of investigation since
Berger's findings (the inventor of
EEG) in the late 1920s. He registered event-related desynchronization of the ongoing alpha rhythm, evidenced by an alpha-amplitude decline after stimulation. The notion of entrainment was introduced in science in the middle of the 20th century as an activation of a timing cue for a biological rhythm, being an inherited
circadian oscillator. This biochemical oscillator in animals cycles with a stable phase and is synchronized with solar time. The entrainment concept describes animals' capacity to synchronize with one another or with external stimuli. In 1971, Professor Aschoff and his colleagues pioneered the study of entrainment in biological systems. Their experiments reported that social cues synchronize human circadian rhythms. Since physiology largely reflects neural activity, this discovery demonstrates neural entrainment (or brainwave entrainment ) and shows that neural entrainment to external periodic stimuli is an essential mechanism in physiology. In 1988, two physiological researchers, Leon Glass and Michael Mackay, contributed to understanding dynamic processes in physiology by explaining "dynamic diseases" that arise from disruptions in the synchronization of vital functions. They explored central theoretical questions about physiological rhythms from the perspectives of biology, medicine, physics, and mathematics. This knowledge provided insights into the development of
complex systems theory, explaining how two or more independent, autonomous oscillators with differing rhythms or frequencies, when situated in proximity and able to interact for long enough, influence each other to a degree dependent on the coupling force. In 1999, Professor Thaut and colleagues demonstrated, in numerous experiments, that acoustic oscillations could entrain movement patterns in patients with neurological disorders, establishing the use of neural entrainment in medicine. In 2018, Professor McCraty found that one's
electrocardiogram signal was registered in another person's
electroencephalogram and elsewhere on the other person's body. While this signal was most potent when people were in contact, it was still detectable when subjects were in proximity but not connected. Professor Gordon and colleagues reported the empirical evidence of similar heartbeats' inter-beat intervals (measured by electrocardiograms) of group members due to an external rhythmical oscillator. Quantitative studies have supported the claim that people's heart rates synchronize when they are in close physical proximity to each other. In 2022, Professor Pejstrup Agger and colleagues invented a novel treatment for Alzheimer's disease, brainwave entrainment using invisible spectral flicker at 40 Hz. In 2023, Professor Thomas J. Nichting from
Eindhoven University of Technology showed evidence of maternal-fetal cardiac coupling, which refers to entrainment of the fetal heart to maternal heart rhythms. The interaction between the
nervous system and the heart is an emerging area of study. In 2024, Latvian professor Igor Val Danilov proposed a theory on the evolutionary basis of brainwave entrainment to external oscillations. He developed a
mother-fetus neurocognitive model, which provides neurophysiological insights into how cognition begins through fetal neural entrainment to the natural oscillations (coined natural neurostimulation) produced by the mother’s body. In 2024, researchers from
MIT, led by Professor TaeHyun Kim, found that daily exposure to light and sound at 40 hertz may protect cancer patients from
chemotherapy-induced damage, memory impairment, and other cognitive effects. ==Origin==