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Bibliographic Details
Main Authors: Krones, Felix H., Walker, Ben, Parsons, Guy, Lyons, Terry, Mahdi, Adam
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2403.06027
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author Krones, Felix H.
Walker, Ben
Parsons, Guy
Lyons, Terry
Mahdi, Adam
author_facet Krones, Felix H.
Walker, Ben
Parsons, Guy
Lyons, Terry
Mahdi, Adam
contents This work showcases our team's (The BEEGees) contributions to the 2023 George B. Moody PhysioNet Challenge. The aim was to predict neurological recovery from coma following cardiac arrest using clinical data and time-series such as multi-channel EEG and ECG signals. Our modelling approach is multimodal, based on two-dimensional spectrogram representations derived from numerous EEG channels, alongside the integration of clinical data and features extracted directly from EEG recordings. Our submitted model achieved a Challenge score of $0.53$ on the hidden test set for predictions made $72$ hours after return of spontaneous circulation. Our study shows the efficacy and limitations of employing transfer learning in medical classification. With regard to prospective implementation, our analysis reveals that the performance of the model is strongly linked to the selection of a decision threshold and exhibits strong variability across data splits.
format Preprint
id arxiv_https___arxiv_org_abs_2403_06027
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Multimodal deep learning approach to predicting neurological recovery from coma after cardiac arrest
Krones, Felix H.
Walker, Ben
Parsons, Guy
Lyons, Terry
Mahdi, Adam
Machine Learning
Signal Processing
This work showcases our team's (The BEEGees) contributions to the 2023 George B. Moody PhysioNet Challenge. The aim was to predict neurological recovery from coma following cardiac arrest using clinical data and time-series such as multi-channel EEG and ECG signals. Our modelling approach is multimodal, based on two-dimensional spectrogram representations derived from numerous EEG channels, alongside the integration of clinical data and features extracted directly from EEG recordings. Our submitted model achieved a Challenge score of $0.53$ on the hidden test set for predictions made $72$ hours after return of spontaneous circulation. Our study shows the efficacy and limitations of employing transfer learning in medical classification. With regard to prospective implementation, our analysis reveals that the performance of the model is strongly linked to the selection of a decision threshold and exhibits strong variability across data splits.
title Multimodal deep learning approach to predicting neurological recovery from coma after cardiac arrest
topic Machine Learning
Signal Processing
url https://arxiv.org/abs/2403.06027