A Subband-Based Information Measure of EEG During Brain Injury and Recovery After Cardiac Arrest

Author

Shin, Hyun-Chool ; Jia, Xiaofeng ; Nickl, Robert ; Geocadin, Romergryko G. ; Thakor, Nitish V.

Author_Institution

Soongsil Univ., Seoul

Volume

55

Issue

8

fYear

2008

Firstpage

1985

Lastpage

1990

Abstract

We propose an improved quantitative measure of EEG during brain injury and recovery after cardiac arrest. In our previous studies, we proposed a measure, information quantity (IQ), to detect the early effects of temperature manipulation on the EEG signals recorded from the scalp. IQ incorporates the wavelet transform and the Shannon entropy in full bands from delta to gamma. Unlike IQ, here we separately calculate IQ in each subband, i.e., the new measure is IQ in each subband. We will call it subband IQ (SIQ). We demonstrate the performance of the proposed method by comparing SIQ with IQ in terms of how well the meausres predict actual neurological outcomes. Thirteen rats, based on 7-min cardiac arrest were used. The experimental results show that the proposed measure was more highly correlated to neurological outcome than IQ.

Keywords

bioelectric phenomena; cardiology; electroencephalography; entropy; neurophysiology; wavelet transforms; EEG signals; Shannon entropy; brain injury; cardiac arrest; neurology; subband information quantity; wavelet transform; Biomedical engineering; Biomedical measurements; Blood flow; Brain injuries; Cardiac arrest; Discrete wavelet transforms; Electroencephalography; Entropy; Scalp; Temperature; Brain injury; EEG; cardiac arrest; entropy; hypothermia; subband; wavelet; Algorithms; Brain Injuries; Diagnosis, Computer-Assisted; Electroencephalography; Heart Arrest; Humans; Recovery of Function; Reproducibility of Results; Sensitivity and Specificity;

fLanguage

English

Journal_Title

Biomedical Engineering, IEEE Transactions on

Publisher

ieee

ISSN

0018-9294

Type

jour

DOI

10.1109/TBME.2008.921093

Filename

4567624