The use of fuzzy integrals and bispectral analysis of the electroencephalogram to predict movement under anesthesia

The objective of this study was to design and evaluate a methodology for estimating the depth of anesthesia in a canine model that integrates electroencephalogram (EEG)-derived autoregressive (AR) parameters, hemodynamic parameters, and the alveolar anesthetic concentration. Using a parametric approach, two separate AR models of order ten were derived for the EEG, one from the third-order cumulant sequence and the other from the autocorrelation lags of the EEG. Since the anesthetic dose versus depth of anesthesia curve is highly nonlinear, a neural network (NN) was chosen as the basic estimator and a multiple NN approach was conceived which took hemodynamic parameters, EEG derived parameters, and anesthetic concentration as input feature vectors. Since the estimation of the depth of anesthesia involves cognitive as well as statistical uncertainties, a fuzzy integral was used to integrate the individual estimates of the various networks and to arrive at the final estimate of the depth of anesthesia. Data from 11 experiments were used to train the NN's which were then tested on nine other experiments. The fuzzy integral of the individual NN estimates (when tested on 43 feature vectors from seven of the nine test experiments) classified 40 (93%) of them correctly, offering a substantial improvement over the individual NN estimates.

[1]  J G Reves,et al.  Monitoring depth of anesthesia. , 1973, Clinical anesthesia.

[2]  P. Sebel,et al.  Prediction of Movement Using Bispectral Electroencephalographic Analysis During Propofol/Alfentanil or Isoflurane/Alfentanil Anesthesia , 1995, Anesthesia and analgesia.

[3]  I Pichlmayr,et al.  Testing the Gaussianity of the Human EEG During Anesthesia , 1992, Methods of Information in Medicine.

[4]  I. Kissin,et al.  General anesthetic action: an obsolete notion? , 1993, Anesthesia and Analgesia.

[5]  Jerry M. Mendel,et al.  Identification of nonminimum phase systems using higher order statistics , 1989, IEEE Trans. Acoust. Speech Signal Process..

[6]  N. T. Smith,et al.  Clinical Signs of Anesthesia , 1972, Anesthesiology.

[7]  R. Lippmann,et al.  An introduction to computing with neural nets , 1987, IEEE ASSP Magazine.

[8]  E. Eger,et al.  Determination and applications of MAC. , 1980, Anesthesiology.

[9]  Chrysostomos L. Nikias,et al.  Bispectrum estimation: A parametric approach , 1985, IEEE Trans. Acoust. Speech Signal Process..

[10]  R. Vishnoi,et al.  Adaptive control of closed-circuit anesthesia , 1991, IEEE Transactions on Biomedical Engineering.

[11]  M. J. Bloom,et al.  BISPECTRAL INDEX AS AN EEG MEASURE OF THE SEDATIVE EFFECT OF ISOFLURANE.: 408 , 1995 .

[12]  C Prys-Roberts,et al.  Anaesthesia: a practical or impractical construct? , 1987, British Journal of Anaesthesia.

[13]  Richard P. Lippmann,et al.  An introduction to computing with neural nets , 1987 .

[14]  G.B. Giannakis,et al.  Cumulant-based order determination of non-Gaussian ARMA models , 1990, IEEE Trans. Acoust. Speech Signal Process..

[15]  Shun-ichi Amari,et al.  Network information criterion-determining the number of hidden units for an artificial neural network model , 1994, IEEE Trans. Neural Networks.

[16]  R. Elul Gaussian Behavior of the Electroencephalogram: Changes during Performance of Mental Task , 1969, Science.

[17]  Donald R. Stanski,et al.  DEPTH OF ANESTHESIA MONITORING TECHNIQUES: AN OVERVIEW , 1999 .

[18]  L. Kearse,et al.  Bispectral Analysis of the Electroencephalogram Correlates with Patient Movement to Skin Incision during Propofol/Nitrous Oxide Anesthesia , 1994, Anesthesiology.

[19]  Sung-Bae Cho,et al.  Combining multiple neural networks by fuzzy integral for robust classification , 1995, IEEE Trans. Syst. Man Cybern..

[20]  Michio Sugeno,et al.  Fuzzy systems theory and its applications , 1991 .