21 January 2009

4 Dimensional EEG Mapping

Tognoli and Kelso developed a novel colorimetric technique that simultaneously maps four dimensions of brain data (magnitude, 2D of cortical surface and time) in order to capture true synchronization in electroencephalographic (EEG) signals. Because of the fourth dimension afforded by this colorimetric method, it is possible to observe and interpret oscillatory activity of the entire brain as it evolves in time, millisecond by millisecond. Moreover, the authors’ method applies to continuous non-averaged EEG data thereby de-emphasizing the notion of “an average brain.” The authors demonstrate that only in continuous EEG can real synchronization be sorted from false synchronization – a kind of synchronization that arises from the spread of electrical fields and volume conduction rather than from genuine interactions between brain areas.
Watching the brain work in "real time" just got a bit easier.
For the brain to achieve its intricate functions such as perception, action, attention and decision making, neural regions have to work together yet still retain their specialized roles. Excess or lack of timely coordination between brain areas lies at the core of a number of psychiatric and neurological disorders such as epilepsy, schizophrenia, autism, Parkinson’s disease, sleep disorders and depression. How the brain is coordinated is a complex and difficult problem in need of new theoretical insights as well as new methods of investigation. In groundbreaking research published in the January 2009 issue and featured on the cover of Progress in Neurobiology, researchers at Florida Atlantic University’s Center for Complex Systems and Brain Sciences in the Charles E. Schmidt College of Science propose a theoretical model of the brain’s coordination dynamics and apply a novel 4D colorimetric method to human neurophysiological data collected in the laboratory.

......In addition to shedding insight on the way the brain normally operates, Tognoli and Kelso’s research provides a much-needed framework to understand the coordination dynamics of brain areas in a variety of pathological conditions. Their approach allows a precise parsing of “brain states” and is likely to open up new ways to study therapeutic interventions, in particular the effects of drugs (pharmaco-dynamics). Their approach will also help improve the design of brain computer interfaces used to help people who are paralyzed.

“In the future, it may be possible to fluently read the processes of the brain from the EEG like one reads notes from a musical score,” said Tognoli. “Our technique is already providing a unique view on brain dynamics. It shows how activity grows and dies in individual brain areas and how multiple areas engage in and disengage from working together as a coordinated team.” _Newswise _ via _ Physorg
It has always been the goal of brain scientists to learn the "language of the brain." How different parts of the brain communicate with each other, and coordinate the dynamic processes involved in consciousness and cognition (2 different things). Combining these dynamic brain studies with "connectomics"-- the working out of brain wiring circuits, will allow much deeper insight into normal and abnormal brain activity.

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