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Main Authors: Boyer-Chammard, Jeanne, Wu, Yinzhe, Zhang, Chenyu, Jewell, Sharon, Strong, Anthony, Yang, Guang, Boutelle, Martyn
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2505.00666
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author Boyer-Chammard, Jeanne
Wu, Yinzhe
Zhang, Chenyu
Jewell, Sharon
Strong, Anthony
Yang, Guang
Boutelle, Martyn
author_facet Boyer-Chammard, Jeanne
Wu, Yinzhe
Zhang, Chenyu
Jewell, Sharon
Strong, Anthony
Yang, Guang
Boutelle, Martyn
contents Prevention of secondary brain injury is a core aim of neurocritical care, with Spreading Depolarizations (SDs) recognized as a significant independent cause. SDs are typically monitored through invasive, high-frequency electrocorticography (ECoG); however, detection remains challenging due to signal artifacts that obscure critical SD-related electrophysiological changes, such as power attenuation and DC drifting. Recent studies suggest spectrogram analysis could improve SD detection; however, brain injury patients often show power reduction across all bands except delta, causing class imbalance. Previous methods focusing solely on delta mitigates imbalance but overlooks features in other frequencies, limiting detection performance. This study explores using multi-frequency spectrogram analysis, revealing that essential SD-related features span multiple frequency bands beyond the most active delta band. This study demonstrated that further integration of both alpha and delta bands could result in enhanced SD detection accuracy by a deep learning model.
format Preprint
id arxiv_https___arxiv_org_abs_2505_00666
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Spreading Depolarization Detection in Electrocorticogram Spectrogram Imaging by Deep Learning: Is It Just About Delta Band?
Boyer-Chammard, Jeanne
Wu, Yinzhe
Zhang, Chenyu
Jewell, Sharon
Strong, Anthony
Yang, Guang
Boutelle, Martyn
Signal Processing
Prevention of secondary brain injury is a core aim of neurocritical care, with Spreading Depolarizations (SDs) recognized as a significant independent cause. SDs are typically monitored through invasive, high-frequency electrocorticography (ECoG); however, detection remains challenging due to signal artifacts that obscure critical SD-related electrophysiological changes, such as power attenuation and DC drifting. Recent studies suggest spectrogram analysis could improve SD detection; however, brain injury patients often show power reduction across all bands except delta, causing class imbalance. Previous methods focusing solely on delta mitigates imbalance but overlooks features in other frequencies, limiting detection performance. This study explores using multi-frequency spectrogram analysis, revealing that essential SD-related features span multiple frequency bands beyond the most active delta band. This study demonstrated that further integration of both alpha and delta bands could result in enhanced SD detection accuracy by a deep learning model.
title Spreading Depolarization Detection in Electrocorticogram Spectrogram Imaging by Deep Learning: Is It Just About Delta Band?
topic Signal Processing
url https://arxiv.org/abs/2505.00666