Title :
Complexity models in physiologic dynamics: a case study on acceleration (+Gz) induced loss of consciousness (G-LOC)
Author :
Cammarota, Joseph P. ; Onaral, Banu ; Hrebien, Leonid
Author_Institution :
Aircraft Div., Naval Air Warfare Center, Warminster, PA, USA
Abstract :
Complex physiologic systems in which the emergent global (observable) behavior results from the interplay among local processes cannot be studied effectively by conventional mathematical models. Such models, which may provide good linear or non-linear input-output data mapping, commonly offer no insight into the microscopic mechanisms underlying the macroscopic behavior. Concepts and tools emerging under the Complexity umbrella account for the interactions of the underlying processes and are therefore better suited to model complex physiologic systems. A model of the reticular activating system under metabolic threat is presented as an example of a physiologic model that duplicates human data and was constructed using some of the tenets of Complexity Theory
Keywords :
physiological models; acceleration-induced consciousness loss; complexity models; complexity theory tenets; emergent global behavior; human data; linear input-output data mapping; local processes interplay; mathematical models; metabolic threat; microscopic mechanisms; nonlinear input-output data mapping; physiologic dynamics; reticular activating system model; Acceleration; Biological system modeling; Complexity theory; Computer aided software engineering; Humans; Ischemic pain; Lab-on-a-chip; Mathematical model; Microscopy; Stress;
Conference_Titel :
Engineering in Medicine and Biology Society, 1994. Engineering Advances: New Opportunities for Biomedical Engineers. Proceedings of the 16th Annual International Conference of the IEEE
Conference_Location :
Baltimore, MD
Print_ISBN :
0-7803-2050-6
DOI :
10.1109/IEMBS.1994.415382
