Your search keyword '"David W. Zhou"' showing total 9 results

1. Electrophysiological correlates of thalamocortical function in acute severe traumatic brain injury

Author

Mary M. Conte, Nicholas D. Schiff, Brian L. Edlow, Joseph T. Giacino, Yelena G. Bodien, William H. Curley, David W. Zhou, Jonathan D. Victor, and Andrea S. Foulkes

Subjects

Coma, medicine.medical_specialty, medicine.diagnostic_test, Traumatic brain injury, business.industry, Neurological examination, Audiology, Electroencephalography, medicine.disease, Arousal, Electrophysiology, Level of consciousness, Intensive care, medicine, medicine.symptom, business

Abstract

Few reliable biomarkers of consciousness exist for patients with acute severe brain injury. Tools assaying the neural networks that modulate consciousness may allow for tracking of recovery. The mesocircuit model, and its instantiation as the ABCD framework, classifies resting-state EEG power spectral densities into categories reflecting widely separated levels of thalamocortical network function and correlates with outcome in post-cardiac arrest coma.We applied the ABCD framework to acute severe traumatic brain injury and tested four hypotheses: 1) EEG channel-level ABCD classifications are spatially heterogeneous and temporally variable; 2) ABCD classifications improve longitudinally, commensurate with the degree of behavioural recovery; 3) ABCD classifications correlate with behavioural level of consciousness; and 4) the Coma Recovery Scale-Revised arousal facilitation protocol improves EEG dynamics along the ABCD scale. In this longitudinal cohort study, we enrolled 20 patients with acute severe traumatic brain injury requiring intensive care and 16 healthy controls. Through visual inspection, channel-level spectra from resting-state EEG were classified based on spectral peaks within frequency bands defined by the ABCD framework: ‘A’ = no peaks above delta (Acutely, 95% of patients demonstrated ‘D’ signals in at least one channel but exhibited heterogeneity in the proportion of different channel-level ABCD classifications (mean percent ‘D’ signals: 37%, range: 0-90%). By contrast, healthy participants and patients at follow-up predominantly demonstrated signals corresponding to intact thalamocortical network function (mean percent ‘D’ signals: 94%). In patients studied acutely, ABCD classifications improved after the Coma Recovery Scale-Revised arousal facilitation protocol (PPPThese findings support the use of the ABCD framework to characterize channel-level EEG dynamics and track fluctuations in functional thalamocortical network integrity in spatial detail.

Published

2021

2. Machine learning of EEG spectra classifies unconsciousness during GABAergic anesthesia

Author

Matthew Keating, Marcus A. Badgeley, Kimaya Lecamwasam, David W. Zhou, Benyamin Meschede-Krasa, Patrick L. Purdon, Gabriel Schamberg, John H. Abel, Emery N. Brown, Sourish Chakravarty, and Indie C. Garwood

Subjects

Male, Physiology, Markov models, Unconsciousness, Electroencephalography, computer.software_genre, Linear Discriminant Analysis, Machine Learning, 0302 clinical medicine, Mathematical and Statistical Techniques, 030202 anesthesiology, Anesthesiology, Medicine and Health Sciences, Anesthesia, Hidden Markov models, Volunteer, Clinical Neurophysiology, Brain Mapping, Principal Component Analysis, Multidisciplinary, medicine.diagnostic_test, Pharmaceutics, Statistics, Brain, Drugs, Signal Processing, Computer-Assisted, Electrophysiology, Physical sciences, Bioassays and Physiological Analysis, Brain Electrophysiology, Medicine, medicine.symptom, Propofol, Anesthetics, Intravenous, medicine.drug, Research Article, medicine.medical_specialty, Consciousness, Imaging Techniques, Sedation, Cognitive Neuroscience, Science, Neurophysiology, Neuroimaging, Surgical and Invasive Medical Procedures, Machine learning, Research and Analysis Methods, Sevoflurane, 03 medical and health sciences, Drug Therapy, medicine, Humans, Pain Management, Statistical Methods, Anesthetics, Pharmacology, business.industry, Electrophysiological Techniques, Biology and Life Sciences, Probability theory, Anesthetic, Multivariate Analysis, Cognitive Science, Artificial intelligence, Clinical Medicine, business, computer, 030217 neurology & neurosurgery, Mathematics, Neuroscience

Abstract

In current anesthesiology practice, anesthesiologists infer the state of unconsciousness without directly monitoring the brain. Drug- and patient-specific electroencephalographic (EEG) signatures of anesthesia-induced unconsciousness have been identified previously. We applied machine learning approaches to construct classification models for real-time tracking of unconscious state during anesthesia-induced unconsciousness. We used cross-validation to select and train the best performing models using 33,159 2s segments of EEG data recorded from 7 healthy volunteers who received increasing infusions of propofol while responding to stimuli to directly assess unconsciousness. Cross-validated models of unconsciousness performed very well when tested on 13,929 2s EEG segments from 3 left-out volunteers collected under the same conditions (median volunteer AUCs 0.99-0.99). Models showed strong generalization when tested on a cohort of 27 surgical patients receiving solely propofol collected in a separate clinical dataset under different circumstances and using different hardware (median patient AUCs 0.95—0.98), with model predictions corresponding with actions taken by the anesthesiologist during the cases. Performance was also strong for 17 patients receiving sevoflurane (alone or in addition to propofol) (median AUCs 0.88—0.92). These results indicate that EEG spectral features can predict unconsciousness, even when tested on a different anesthetic that acts with a similar neural mechanism. With high performance predictions of unconsciousness, we can accurately monitor anesthetic state, and this approach may be used to engineer infusion pumps to intelligibly respond to patients’ neural activity.

Published

2021

3. Automated tracking of level of consciousness and delirium in critical illness using deep learning

Author

Haoqi Sun, Emily J. Boyle, Oluwaseun Akeju, M. Brandon Westover, Wendong Ge, Eyal Y. Kimchi, David W. Zhou, Wei-Long Zheng, Lauren M. McClain, and Sunil B. Nagaraj

Subjects

medicine.medical_specialty, Sedation, Medicine (miscellaneous), Health Informatics, Disorders of consciousness, ICU PATIENTS, Electroencephalography, lcsh:Computer applications to medicine. Medical informatics, Article, CLASSIFICATION, VALIDATION, 03 medical and health sciences, 0302 clinical medicine, Level of consciousness, Health Information Management, medicine, 030212 general & internal medicine, EEG, Elective surgery, VALIDITY, medicine.diagnostic_test, business.industry, Deep learning, Diagnostic markers, Translational research, medicine.disease, Computer Science Applications, TIME, AGITATION-SEDATION SCALE, Critical illness, Emergency medicine, RELIABILITY, ELECTROENCEPHALOGRAPHY, Delirium, lcsh:R858-859.7, Artificial intelligence, medicine.symptom, business, 030217 neurology & neurosurgery

Abstract

Over- and under-sedation are common in the ICU, and contribute to poor ICU outcomes including delirium. Behavioral assessments, such as Richmond Agitation-Sedation Scale (RASS) for monitoring levels of sedation and Confusion Assessment Method for the ICU (CAM-ICU) for detecting signs of delirium, are often used. As an alternative, brain monitoring with electroencephalography (EEG) has been proposed in the operating room, but is challenging to implement in ICU due to the differences between critical illness and elective surgery, as well as the duration of sedation. Here we present a deep learning model based on a combination of convolutional and recurrent neural networks that automatically tracks both the level of consciousness and delirium using frontal EEG signals in the ICU. For level of consciousness, the system achieves a median accuracy of 70% when allowing prediction to be within one RASS level difference across all patients, which is comparable or higher than the median technician–nurse agreement at 59%. For delirium, the system achieves an AUC of 0.80 with 69% sensitivity and 83% specificity at the optimal operating point. The results show it is feasible to continuously track level of consciousness and delirium in the ICU.

Published

2019

4. Automatic Classification of Sedation Levels in ICU Patients Using Heart Rate Variability

Author

Eric Rosenthal, Lauren M. McClain, Siddharth Biswal, Patrick L. Purdon, M. Brandon Westover, David W. Zhou, and Sunil B. Nagaraj

Subjects

Adult, Male, Icu patients, Critical Care, Sedation, Conscious Sedation, Pilot Projects, Critical Care and Intensive Care Medicine, Article, Electrocardiography, 03 medical and health sciences, 0302 clinical medicine, Heart Rate, 030202 anesthesiology, medicine, Humans, Hypnotics and Sedatives, Heart rate variability, Prospective Studies, General hospital, Prospective cohort study, Psychomotor Agitation, Aged, medicine.diagnostic_test, business.industry, Middle Aged, Respiration, Artificial, Multicenter study, Anesthesia, Female, medicine.symptom, business, 030217 neurology & neurosurgery

Abstract

To explore the potential value of heart rate variability features for automated monitoring of sedation levels in mechanically ventilated ICU patients.Multicenter, pilot study.Several ICUs at Massachusetts General Hospital, Boston, MA.Electrocardiogram recordings from 40 mechanically ventilated adult patients receiving sedatives in an ICU setting were used to develop and test the proposed automated system.Richmond Agitation-Sedation Scale scores were acquired prospectively to assess patient sedation levels and were used as ground truth. Richmond Agitation-Sedation Scale scores were grouped into four levels, denoted "unarousable" (Richmond Agitation- Sedation Scale = -5, -4), "sedated" (-3, -2, -1), "awake" (0), "agitated" (+1, +2, +3, +4). A multiclass support vector machine algorithm was used for classification. Classifier training and performance evaluations were carried out using leave-oneout cross validation. An overall accuracy of 69% was achieved for discriminating between the four levels of sedation. The proposed system was able to reliably discriminate (accuracy = 79%) between sedated (Richmond Agitation-Sedation Scale0) and nonsedated states (Richmond Agitation-Sedation Scale0).With further refinement, the methodology reported herein could lead to a fully automated system for depth of sedation monitoring. By enabling monitoring to be continuous, such technology may help clinical staff to monitor sedation levels more effectively and to reduce complications related to over- and undersedation.

Published

2016

5. Age-Dependent Changes in the Propofol-Induced Electroencephalogram in Children With Autism Spectrum Disorder

Author

Elisa C. Walsh, Johanna M. Lee, Kristina Terzakis, David W. Zhou, Sara Burns, Timothy M. Buie, Paul G. Firth, Erik S. Shank, Timothy T. Houle, Emery N. Brown, Patrick L. Purdon, Institute for Medical Engineering and Science, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, and Brown, Emery Neal

Subjects

Pediatrics, medicine.medical_specialty, Cognitive Neuroscience, Sedation, Neuroscience (miscellaneous), Electroencephalography, behavioral disciplines and activities, lcsh:RC321-571, 03 medical and health sciences, Cellular and Molecular Neuroscience, 0302 clinical medicine, Developmental Neuroscience, 030202 anesthesiology, Post-hoc analysis, mental disorders, Medicine, electroencephalography (EEG), Risk factor, lcsh:Neurosciences. Biological psychiatry. Neuropsychiatry, Original Research, medicine.diagnostic_test, propofol, business.industry, medicine.disease, general anesthesia, Burst suppression, Autism spectrum disorder, autism spectrum disorder (ASD), medicine.symptom, business, Propofol, gamma aminobutyric acid (GABA), 030217 neurology & neurosurgery, Neurotypical, medicine.drug, Neuroscience

Abstract

Patients with autism spectrum disorder (ASD) often require sedation or general anesthesia. ASD is thought to arise from deficits in GABAergic signaling leading to abnormal neurodevelopment. We sought to investigate differences in how ASD patients respond to the GABAergic drug propofol by comparing the propofol-induced electroencephalogram (EEG) of ASD and neurotypical (NT) patients. This investigation was a prospective observational study. Continuous 4-channel frontal EEG was recorded during routine anesthetic care of patients undergoing endoscopic procedures between July 1, 2014 and May 1, 2016. Study patients were defined as those with previously diagnosed ASD by DSM-V criteria, aged 2–30 years old. NT patients were defined as those lacking neurological or psychiatric abnormalities, aged 2–30 years old. The primary outcome was changes in propofol-induced alpha (8–13 Hz) and slow (0.1–1 Hz) oscillation power by age. A post hoc analysis was performed to characterize incidence of burst suppression during propofol anesthesia. The primary risk factor of interest was a prior diagnosis of ASD. Outcomes were compared between ASD and NT patients using Bayesian methods. Compared to NT patients, slow oscillation power was initially higher in ASD patients (17.05 vs. 14.20 dB at 2.33 years), but progressively declined with age (11.56 vs. 13.95 dB at 22.5 years). Frontal alpha power was initially lower in ASD patients (17.65 vs. 18.86 dB at 5.42 years) and continued to decline with age (6.37 vs. 11.89 dB at 22.5 years). The incidence of burst suppression was significantly higher in ASD vs. NT patients (23.0% vs. 12.2%, p < 0.01) despite reduced total propofol dosing in ASD patients. Ultimately, we found that ASD patients respond differently to propofol compared to NT patients. A similar pattern of decreased alpha power and increased sensitivity to burst suppression develops in older NT adults; one interpretation of our data could be that ASD patients undergo a form of accelerated neuronal aging in adolescence. Our results suggest that investigations of the propofol-induced EEG in ASD patients may enable insights into the underlying differences in neural circuitry of ASD and yield safer practices for managing patients with ASD.

Published

2018

6. Electroencephalogram based Detection of Deep Sedation in ICU Patients Using Atomic Decomposition

Author

Emily J. Boyle, Sowmya M. Ramaswamy, Oluwaseun Akeju, Patrick L. Purdon, David W. Zhou, Sunil B. Nagaraj, Siddharth Biswal, M. Brandon Westover, and Lauren M. McClain

Subjects

Male, Support Vector Machine, Consciousness, Critical Care, Computer science, Sedation, 0206 medical engineering, Feature extraction, Biomedical Engineering, 02 engineering and technology, Electroencephalography, Article, law.invention, 03 medical and health sciences, 0302 clinical medicine, 030202 anesthesiology, law, medicine, Entropy (information theory), Humans, Aged, medicine.diagnostic_test, business.industry, Pattern recognition, Signal Processing, Computer-Assisted, Middle Aged, 020601 biomedical engineering, Intensive care unit, Intensive Care Units, Female, Artificial intelligence, medicine.symptom, Deep Sedation, business

Abstract

Objective : This study was performed to evaluate how well states of deep sedation in ICU patients can be detected from the frontal electroencephalogram (EEG) using features based on the method of atomic decomposition (AD). Methods : We analyzed a clinical dataset of 20 min of EEG recordings per patient from 44 mechanically ventilated adult patients receiving sedatives in an intensive care unit (ICU) setting. Several features derived from AD of the EEG signal were used to discriminate between awake and sedated states. We trained support vector machine (SVM) classifiers using AD features and compared the classification performance with SVM classifiers trained using standard spectral and entropy features using leave-one-subject-out validation. The potential of each feature to discriminate between awake and sedated states was quantified using area under the receiver operating characteristic curve (AUC). Results : The sedation level classification system using AD was able to reliably discriminate between sedated and awake states achieving an average AUC of 0.90, which was significantly better ( $p ) than performance achieved using spectral (AUC = 0.86) and entropy (AUC = 0.81) domain features. A combined feature set consisting of AD, entropy, and spectral features provided better discrimination (AUC = 0.91, $p ) than any individual feature set. Conclusions : Features derived from the atomic decomposition of EEG signals provide useful discriminative information about the depth of sedation in ICU patients. Significance : With further refinement and external validation, the proposed system may be able to assist clinical staff with continuous surveillance of sedation levels in mechanically ventilated critically ill ICU patients.

Published

2018

7. The Ageing Brain: Age-dependent changes in the electroencephalogram during propofol and sevoflurane general anaesthesia

Author

Patrick L. Purdon, Oluwaseun Akeju, Kara J. Pavone, David W. Zhou, Emery N. Brown, Johanna M. Lee, Aaron L. Sampson, Anne C. Smith, and Ken Solt

Subjects

Adult, Male, Methyl Ethers, Aging, Adolescent, Alpha (ethology), Anesthesia, General, Electroencephalography, Sevoflurane, Young Adult, medicine, Humans, General anaesthesia, Young adult, Propofol, Aged, Anesthetics, Aged, 80 and over, medicine.diagnostic_test, business.industry, Middle Aged, Burst suppression, Anesthesiology and Pain Medicine, Ageing, Anesthesia, Female, business, medicine.drug

Abstract

Background Anaesthetic drugs act at sites within the brain that undergo profound changes during typical ageing. We postulated that anaesthesia-induced brain dynamics observed in the EEG change with age. Methods We analysed the EEG in 155 patients aged 18–90 yr who received propofol (n=60) or sevoflurane (n=95) as the primary anaesthetic. The EEG spectrum and coherence were estimated throughout a 2 min period of stable anaesthetic maintenance. Age-related effects were characterized by analysing power and coherence as a function of age using linear regression and by comparing the power spectrum and coherence in young (18- to 38-yr-old) and elderly (70- to 90-yr-old) patients. Results Power across all frequency bands decreased significantly with age for both propofol and sevoflurane; elderly patients showed EEG oscillations ∼2- to 3-fold smaller in amplitude than younger adults. The qualitative form of the EEG appeared similar regardless of age, showing prominent alpha (8–12 Hz) and slow (0.1–1 Hz) oscillations. However, alpha band dynamics showed specific age-related changes. In elderly compared with young patients, alpha power decreased more than slow power, and alpha coherence and peak frequency were significantly lower. Older patients were more likely to experience burst suppression. Conclusions These profound age-related changes in the EEG are consistent with known neurobiological and neuroanatomical changes that occur during typical ageing. Commercial EEG-based depth-of-anaesthesia indices do not account for age and are therefore likely to be inaccurate in elderly patients. In contrast, monitoring the unprocessed EEG and its spectrogram can account for age and individual patient characteristics.

Published

2015

8. Heart rate variability as a biomarker for sedation depth estimation in ICU patients

Author

Eric Rosenthal, Sunil B. Nagaraj, Emily J. Boyle, Lauren M. McClain, Sowmya M. Ramaswamy, Patrick L. Purdon, Siddharth Biswal, David W. Zhou, and M. Brandon Westover

Subjects

Adult, Male, Icu patients, medicine.medical_specialty, Sedation, 0206 medical engineering, Conscious Sedation, 02 engineering and technology, Prediction system, Article, Cross-validation, Automation, Young Adult, 03 medical and health sciences, 0302 clinical medicine, Heart Rate, Humans, Heart rate variability, Medicine, Intensive care medicine, Aged, Demography, Aged, 80 and over, medicine.diagnostic_test, Adult patients, business.industry, Signal Processing, Computer-Assisted, Middle Aged, 020601 biomedical engineering, Intensive Care Units, ROC Curve, Clinical staff, Female, medicine.symptom, Artifacts, business, Electrocardiography, Biomarkers, 030217 neurology & neurosurgery

Abstract

An automated patient-specific system to classify the level of sedation in ICU patients using heart rate variability signal is presented in this paper. ECG from 70 mechanically ventilated adult patients with administered sedatives in an ICU setting were used to develop a support vector machine based system for sedation depth monitoring using several heart rate variability measures. A leave-one-subject-out cross validation was used for classifier training and performance evaluations. The proposed patient-specific system provided a sensitivity, specificity and an AUC of 64%, 84.8% and 0.72, respectively. It is hoped that with the help of additional physiological signals the proposed patient-specific sedation level prediction system could lead to a fully automated multimodal system to assist clinical staff in ICUs to interpret the sedation level of the patient.

Published

2016

9. Patient-Specific Classification of ICU Sedation Levels From Heart Rate Variability*

Author

Sunil B. Nagaraj, Riccardo Barbieri, Sadeq A. Quraishi, Siddharth Biswal, M. Brandon Westover, Patrick L. Purdon, Lauren M. McClain, David W. Zhou, Oluwaseun Akeju, Emily J. Boyle, and Ednan K. Bajwa

Subjects

Male, medicine.medical_specialty, Support Vector Machine, Sedation, Pilot Projects, 030204 cardiovascular system & hematology, Richmond Agitation-Sedation Scale, Critical Care and Intensive Care Medicine, heart rate variability, intensive care, Richmond Agitation Sedation Scale, sedation monitoring, support vector machine, Aged, Algorithms, Anesthesia, Boston, Female, Heart Rate, Humans, Intensive Care Units, Middle Aged, Respiration, Artificial, Electrocardiography, 03 medical and health sciences, 0302 clinical medicine, Intensive care, Heart rate, Medicine, Heart rate variability, General hospital, medicine.diagnostic_test, business.industry, Respiration, Patient specific, 3. Good health, 030228 respiratory system, Artificial, Emergency medicine, medicine.symptom, business

Abstract

To develop a personalizable algorithm to discriminate between sedation levels in ICU patients based on heart rate variability.Multicenter, pilot study.Several ICUs at Massachusetts General Hospital, Boston, MA.We gathered 21,912 hours of routine electrocardiogram recordings from a heterogenous group of 70 adult ICU patients. All patients included in the study were mechanically ventilated and were receiving sedatives.As "ground truth" for developing our method, we used Richmond Agitation Sedation Scale scores grouped into four levels denoted "comatose" (-5), "deeply sedated" (-4 to -3), "lightly sedated" (-2 to 0), and "agitated" (+1 to +4). We trained a support vector machine learning algorithm to calculate the probability of each sedation level from heart rate variability measures derived from the electrocardiogram. To estimate algorithm performance, we calculated leave-one-subject out cross-validated accuracy. The patient-independent version of the proposed system discriminated between the four sedation levels with an overall accuracy of 59%. Upon personalizing the system supplementing the training data with patient-specific calibration data, consisting of an individual's labeled heart rate variability epochs from the preceding 24 hours, accuracy improved to 67%. The personalized system discriminated between light- and deep-sedation states with an average accuracy of 75%.With further refinement, the methodology reported herein could lead to a fully automated system for depth of sedation monitoring. By enabling monitoring to be continuous, such technology may help clinical staff to monitor sedation levels more effectively and to reduce complications related to over- and under sedation.