Resting-State EEG Signature of Early Consciousness Recovery in Comatose Patients with Traumatic Brain Injury

Overview

Journal Neurocrit Care

Specialty Critical Care

Date 2024 May 29

PMID 38811512

Authors

Ayham Alkhachroum

Emilia Flo

Brian Manolovitz

Holly Cohan

Berje Shammassian

Danielle Bass

Gabriela Aklepi

Esther Monexe

Pardis Ghamasaee

Evie Sobczak

Daniel Samano

Ana Bolanos Saavedra

Nina Massad

Mohan Kottapally

Amedeo Merenda

Joacir Graciolli Cordeiro

Jonathan Jagid

Andres M Kanner

Tatjana Rundek

Kristine OPhelan

Jan Claassen

Jacobo D Sitt

Affiliations

Soon will be listed here.

Abstract

Background: Resting-state electroencephalography (rsEEG) is usually obtained to assess seizures in comatose patients with traumatic brain injury (TBI). We aim to investigate rsEEG measures and their prediction of early recovery of consciousness in patients with TBI.

Methods: This is a retrospective study of comatose patients with TBI who were admitted to a trauma center (October 2013 to January 2022). Demographics, basic clinical data, imaging characteristics, and EEGs were collected. We calculated the following using 10-min rsEEGs: power spectral density, permutation entropy (complexity measure), weighted symbolic mutual information (wSMI, global information sharing measure), Kolmogorov complexity (Kolcom, complexity measure), and heart-evoked potentials (the averaged EEG signal relative to the corresponding QRS complex on electrocardiography). We evaluated the prediction of consciousness recovery before hospital discharge using clinical, imaging, and rsEEG data via a support vector machine.

Results: We studied 113 of 134 (84%) patients with rsEEGs. A total of 73 (65%) patients recovered consciousness before discharge. Patients who recovered consciousness were younger (40 vs. 50 years, p = 0.01). Patients who recovered also had higher Kolcom (U = 1688, p = 0.01), increased beta power (U = 1,652 p = 0.003) with higher variability across channels (U = 1534, p = 0.034) and epochs (U = 1711, p = 0.004), lower delta power (U = 981, p = 0.04), and higher connectivity across time and channels as measured by wSMI in the theta band (U = 1636, p = 0.026; U = 1639, p = 0.024) than those who did not recover. The area under the receiver operating characteristic curve for rsEEG was higher than that for clinical data (using age, motor response, pupil reactivity) and higher than that for the Marshall computed tomography classification (0.69 vs. 0.66 vs. 0.56, respectively; p < 0.001).

Conclusions: We describe the rsEEG signature in recovery of consciousness prior to discharge in comatose patients with TBI. rsEEG measures performed modestly better than the clinical and imaging data in predicting recovery.

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