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Putting the Brain to Work: Neuroergonomics Past, Present, and Future

George Mason University, Fairfax, Virginia, rparasur{at}gmu.edu

Glenn F. Wilson

Physiometrex, Dayton, Ohio

Objective: The authors describe research and applications in prominent areas of neuroergonomics. Background: Because human factors/ergonomics examines behavior and mind at work, it should include the study of brain mechanisms underlying human performance. Methods: Neuroergonomic studies are reviewed in four areas: workload and vigilance, adaptive automation, neuroengineering, and molecular genetics and individual differences. Results: Neuroimaging studies have helped identify the components of mental workload, workload assessment in complex tasks, and resource depletion in vigilance. Furthermore, real-time neurocognitive assessment of workload can trigger adaptive automation. Neural measures can also drive brain-computer interfaces to provide disabled users new communication channels. Finally, variants of particular genes can be associated with individual differences in specific cognitive functions. Conclusions: Neuroergonomics shows that considering what makes work possible — the human brain — can enrich understanding of the use of technology by humans and can inform technological design. Application: Applications of neuroergonomics include the assessment of operator workload and vigilance, implementation of real-time adaptive automation, neuroengineering for people with disabilities, and design of selection and training methods.

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Human Factors: The Journal of the Human Factors and Ergonomics Society, Vol. 50, No. 3, 468-474 (2008)
DOI: 10.1518/001872008X288349


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