Your search keyword '"Roy RJ"' showing total 9 results

1. Reviews of Modeling Techniques for Neuromonitoring Depth of Anesthesia.

Author

Zhang XS, Huang JW, and Roy RJ

Subjects

Algorithms, Anesthesiology standards, Fuzzy Logic, Humans, Monitoring, Intraoperative methods, Anesthesia methods, Anesthesia standards, Anesthesiology methods, Intraoperative Neurophysiological Monitoring methods, Models, Biological

Abstract

This article reviews the various modeling techniques for neuromonitoring depth of anesthesia (DOA). Traditional techniques such as parametric, predictive, optimal, and adaptive modeling; proportional, integral, derivative (PID) modeling; together with modern techniques such as bispectral-based, artificial neural-network-based, fuzzy logic, and neuro-fuzzy modeling, bring us to the current state of the art in DOA neuromonitoring. This article reviews historical information about each of the modern techniques and provides an example demonstrating its implementation; reviews drug pharmacokinetic/pharmacodynamic (PK/PD) and drug interaction PK/PD modeling techniques for a balanced total intravenous anesthesia (TIVA) administration; and discusses the existing technical problems and clinical challenges, suggesting new techniques necessary for the future development of a DOA monitoring and control system.

Published

2017

2. Modeling for neuromonitoring depth of anesthesia.

Author

Zhang XS, Huang JW, and Roy RJ

Subjects

Animals, Dogs, Fuzzy Logic, Humans, Monitoring, Physiologic methods, Monitoring, Physiologic trends, Predictive Value of Tests, Rats, Anesthesia methods, Models, Neurological, Monitoring, Intraoperative methods

Abstract

This article reviews the various modeling techniques for neuromonitoring depth of anesthesia (DOA). Traditional techniques such as parametric, predictive, optimal, and adaptive modeling, proportional, integral, derivative (PID) modeling, together with modern techniques such as bispectral-based, artificial neural-network-based, fuzzy logic, and neuro-fuzzy modeling, bring us to the current state of the art in DOA neuromonitoring. This article reviews historical information about each of the modern techniques and provides an example demonstrating its implementation; reviews drug pharmacokinetic/pharmacodynamic (PK/PD) and drug interaction PK/PD modeling techniques for a balanced total intravenous anesthesia (TIVA) administration; and discusses the existing technical problems and clinical challenges, suggesting new techniques necessary for the future development of a DOA monitoring and control system.

Published

2002

3. EEG complexity as a measure of depth of anesthesia for patients.

Author

Zhang XS, Roy RJ, and Jensen EW

Subjects

Adult, Aged, Aged, 80 and over, Algorithms, Brain physiology, Confidence Intervals, Consciousness physiology, Female, Humans, Male, Middle Aged, Monitoring, Physiologic methods, Sleep physiology, Vascular Surgical Procedures, Anesthesia methods, Electroencephalography, Models, Neurological, Nonlinear Dynamics

Abstract

A new approach for quantifying the relationship between brain activity patterns and depth of anesthesia (DOA) is presented by analyzing the spatio-temporal patterns in the electroencephalogram (EEG) using Lempel-Ziv complexity analysis. Twenty-seven patients undergoing vascular surgery were studied under general anesthesia with sevoflurane, isoflurane, propofol, or desflurane. The EEG was recorded continuously during the procedure and patients' anesthesia states were assessed according to the responsiveness component of the observer's assessment of alertness/sedation (OAA/S) score. An OAA/S score of zero or one was considered asleep and two or greater was considered awake. Complexity of the EEG was quantitatively estimated by the measure C(n), whose performance in discriminating awake and asleep states was analyzed by statistics for different anesthetic techniques and different patient populations. Compared with other measures, such as approximate entropy, spectral entropy, and median frequency, C(n) not only demonstrates better performance (93% accuracy) across all of the patients, but also is an easier algorithm to implement for real-time use. The study shows that C(n) is a very useful and promising EEG-derived parameter for characterizing the (DOA) under clinical situations.

Published

2001

4. Discrimination of anesthetic states using mid-latency auditory evoked potential and artificial neural networks.

Author

Zhang XS, Roy RJ, Schwender D, and Daunderer M

Subjects

Anesthetics, Intravenous administration & dosage, Biomedical Engineering, Humans, Propofol administration & dosage, Anesthesia, Evoked Potentials, Auditory drug effects, Neural Networks, Computer

Abstract

This study was undertaken to determine whether artificial neural network (ANN) processing of mid-latency auditory evoked potentials (MLAEPs) can identify different anesthetic states during propofol anesthesia, and to determine those parameters that are most useful in the identification process. Twenty-one patients undergoing elective abdominal surgery were studied. To maintain general anesthesia, the patients received propofol (3-5 mgkg(-1) h(-1) intravenously). Epidural analgesia at the level of T4-5 blocked painful stimuli. MLAEP was recorded continuously with patients awake, during induction, during maintenance of general anesthesia, and during emergence until the patients were recovered from anesthesia. Latencies of the 5 MLAEP peaks and three peak to peak amplitudes were measured, along with hemodynamic parameters (heart rate, systolic, and diastolic arterial blood pressure). Four-layer ANNs were used to model the relationship between the parameters of the MLAEP and the four different states (awake, adequate anesthesia, during/before intraoperative movement, and emergence from anesthesia). The best identification accuracy was obtained using only the five latencies. The combination of five latencies and three amplitudes did not improve the identification accuracy. Use of the only the three hemodynamic parameters produced a much poorer identification. This study suggests that the MLAEP has useful information for identifying different anesthetic states, especially in its latencies. A nonlinear discrimination approach, such as the ANN, can effectively capture the relation between the MLAEP patterns and the different states of anesthesia.

Published

2001

5. Derived fuzzy knowledge model for estimating the depth of anesthesia.

Author

Zhang XS and Roy RJ

Subjects

Algorithms, Animals, Dogs, Electroencephalography, Halothane administration & dosage, Isoflurane administration & dosage, Monitoring, Physiologic, Movement, Neural Networks, Computer, Nonlinear Dynamics, Online Systems, Predictive Value of Tests, Propofol administration & dosage, Reproducibility of Results, Signal Processing, Computer-Assisted, Anesthesia methods, Computer Simulation, Fuzzy Logic, Models, Biological

Abstract

Reliable and noninvasive monitoring of the depth of anesthesia (DOA) is highly desirable. Based on adaptive network-based fuzzy inference system (ANFIS) modeling, a derived fuzzy knowledge model is proposed for quantitatively estimating the DOA and validate it by 30 experiments using 15 dogs undergoing anesthesia with three different anesthetic regimens (propofol, isoflurane, and halothane). By eliciting fuzzy if-then rules, the model provides a way to address the DOA estimation problem by using electroencephalogram-derived parameters. The parameters include two new measures (complexity and regularity) extracted by nonlinear quantitative analyses, as well as spectral entropy. The model demonstrates good performance in discriminating awake and asleep states for three common anesthetic regimens (accuracy 90.3 % for propofol, 92.7 % for isoflurane, and 89.1% for halothane), real-time feasibility, and generalization ability (accuracy 85.9% across the three regimens). The proposed fuzzy knowledge model is a promising candidate as an effective tool for continuous assessment of the DOA.

Published

2001

6. Simultaneous regulation of hemodynamic and anesthetic states: a simulation study.

Author

Rao RR, Bequette BW, and Roy RJ

Subjects

Anesthetics, Intravenous pharmacokinetics, Anesthetics, Intravenous pharmacology, Animals, Biomedical Engineering, Coronary Artery Bypass, Critical Care, Dogs, Feedback, Heart Failure physiopathology, Humans, Models, Cardiovascular, Propofol pharmacokinetics, Propofol pharmacology, Anesthesia, Hemodynamics drug effects

Abstract

A model predictive control strategy to simultaneously regulate hemodynamic and anesthetic variables in critical care patients is presented. A nonlinear canine circulatory model, which has been used to study the effect of inotropic and vasoactive drugs on hemodynamic variables, has been extended to include propofol pharmacokinetics and pharmacodynamics. Propofol blood concentration is used as a measure for depth of anesthesia. The simulation model is used to design and test the control strategy. The optimization-based model predictive control strategy assures that constraints imposed on the drug infusion rates are met. The physician always remains "in the loop" and serves as the "primary controller" by making propofol blood concentration setpoint changes based on observations about anesthetic depth. Results are shown for three simulated cases: (i) congestive heart failure, (ii) postcoronary artery bypass, and (iii) acute changes in hemodynamic variables.

Published

2000

7. Predicting movement during anaesthesia by complexity analysis of electroencephalograms.

Author

Zhang XS and Roy RJ

Subjects

Animals, Dogs, Anesthesia, Electroencephalography, Movement, Neural Networks, Computer, Signal Processing, Computer-Assisted

Abstract

A new approach to predicting movement during anaesthesia by using complexity analysis of electroencephalograms (EEG) signals is presented. The raw EEG signal is first decomposed into six consecutive different scaling components by wavelet transform on the basis of its self-similarity. The Lempel-Ziv complexity measures C(n) are extracted from the raw EEG and its corresponding components by complexity analysis. Prediction of movement during anaesthesia is then made by a four-layer artificial neural network (ANN) using the C(n)s. The combination of these three different approaches enables the system to address the non-analytical, non-stationary, non-linear and dynamical properties of the EEG. From 20 dog experiments, 109 distinct EEG recordings are collected under isoflurane anaesthesia. Testing the ANN using the 'drop one dog' method, the performance obtained for the system in detecting movement is: sensitivity 88%, specificity 97% and accuracy 92%. Comparisons with other methods, such as spectral edge frequency, median frequency and principal component analysis, show that the proposed system has a certain advantage. This new method is computationally fast and well suited for realtime clinical implementation.

Published

1999

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

Author

Muthuswamy J and Roy RJ

Subjects

Anesthetics, Inhalation, Animals, Discriminant Analysis, Dogs, Equipment Design, Hemodynamics, Isoflurane, Linear Models, Models, Neurological, Monitoring, Intraoperative instrumentation, Monitoring, Intraoperative methods, Predictive Value of Tests, Sensitivity and Specificity, Anesthesia, Electroencephalography instrumentation, Fuzzy Logic, Movement physiology, Neural Networks, Computer, Signal Processing, Computer-Assisted

Abstract

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 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.

Published

1999

9. Time-frequency spectral representation of the EEG as an aid in the detection of depth of anesthesia.

Author

Nayak A, Roy RJ, and Sharma A

Subjects

Animals, Dogs, Drug Evaluation, Preclinical, Neurologic Examination, Time Factors, Anesthesia, Drug Monitoring methods, Electroencephalography methods, Halothane pharmacology, Monitoring, Intraoperative methods, Signal Processing, Computer-Assisted, Wakefulness drug effects

Abstract

A time-frequency spectral representation (TFSR) has been used to study the nonstationary information in the EEG as an aid in determining the anesthetic depth. This paper uses a TFSR with an exponential weighting function for the purpose. Raw EEG data were collected form 10 mongrel dogs at various levels of halothane anesthesia. Depth of anesthesia was tested by observing the response to tail clamping, which is considered a supramaximal stimulus in dogs. A positive response was graded as awake (depth 0), and a negative response was graded as asleep (depth 1). The EEG obtained during a period of 30 sec tail clamp was processed into TFSRs. It was observed that at depth 0, the spectrum becomes localized in time and frequency. The percentage of energy in the delta (1-3.5 Hz) and theta (3.5-7.5 Hz) frequency bands increased. At depth 1, the spectrum remained unchanged throughout the period of tail clamp. The performance of the TFSR in detecting the patient's awareness was also compared with the power spectrum. It was concluded that under certain anesthetic conditions, the TFSR is superior to the power spectrum.

Published

1994