• DocumentCode
    1358917
  • Title

    Bayesian Quantitative Electrophysiology and Its Multiple Applications in Bioengineering

  • Author

    Barr, Roger C. ; Nolte, Loren W. ; Pollard, Andrew E.

  • Author_Institution
    Depts. of Biomed. Eng. & Pediatrics, Duke Univ., Durham, NC, USA
  • Volume
    3
  • fYear
    2010
  • fDate
    7/2/1905 12:00:00 AM
  • Firstpage
    155
  • Lastpage
    168
  • Abstract
    Bayesian interpretation of observations began in the early 1700s, and scientific electrophysiology began in the late 1700s. For two centuries these two fields developed mostly separately. In part that was because quantitative Bayesian interpretation, in principle a powerful method of relating measurements to their underlying sources, often required too many steps to be feasible with hand calculation in real applications. As computer power became widespread in the later 1900s, Bayesian models and interpretation moved rapidly but unevenly from the domain of mathematical statistics into applications. Use of Bayesian models now is growing rapidly in electrophysiology. Bayesian models are well suited to the electrophysiological environment, allowing a direct and natural way to express what is known (and unknown) and to evaluate which one of many alternatives is most likely the source of the observations, and the closely related receiver operating characteristic (ROC) curve is a powerful tool in making decisions. Yet, in general, many people would ask what such models are for, in electrophysiology, and what particular advantages such models provide. So to examine this question in particular, this review identifies a number of electrophysiological papers in bioengineering arising from questions in several organ systems to see where Bayesian electrophysiological models or ROC curves were important to the results that were achieved.
  • Keywords
    Bayes methods; bioelectric phenomena; biomedical engineering; biomedical measurement; sensitivity analysis; Bayesian electrophysiological model; Bayesian model; Bayesian quantitative electrophysiology; bioengineering; computer power; electrophysiological environment; mathematical statistics; quantitative Bayesian interpretation; receiver operating characteristic curve; Bayesian methods; Biological system modeling; Biomedical engineering; Mathematical model; Probability density function; Bayes procedures; bioelectricity; electrophysiology; modeling; Bayes Theorem; Biomedical Engineering; Brain; Electrophysiological Phenomena; Genomics; Humans; Models, Statistical; Models, Theoretical; ROC Curve; Vision, Ocular;
  • fLanguage
    English
  • Journal_Title
    Biomedical Engineering, IEEE Reviews in
  • Publisher
    ieee
  • ISSN
    1937-3333
  • Type

    jour

  • DOI
    10.1109/RBME.2010.2089375
  • Filename
    5607294