Impedance-based Ventilation Detection and Signal Quality Control during Out-of-Hospital Cardiopulmonary Resuscitation

Feedback on ventilation could help improve cardiopulmonary resuscitation quality and survival from out-of-hospital cardiac arrest (OHCA). However, current technology that monitors ventilation during OHCA is very limited. Thoracic impedance (TI) is sensitive to air volume changes in the lungs, allowi...

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Bibliographic Details
Published in:IEEE journal of biomedical and health informatics 2023-06, Vol.27 (6), p.1-11
Main Authors: Jaureguibeitia, Xabier, Aramendi, Elisabete, Wang, Henry E., Idris, Ahamed H.
Format: Article
Language:English
Subjects:
Adaptive filter
Adaptive filters
Algorithms
Biomedical monitoring
Capnography
Carbon dioxide
Cardiac arrest
Cardiopulmonary resuscitation
cardiopulmonary resuscitation (CPR)
Cardiopulmonary Resuscitation - methods
Chest
Compression
CPR
Electric Impedance
Feedback
Fluctuations
Force
Hospitals
Humans
Impedance
Lung
Mathematical models
Monitoring
Neural networks
Out-of-Hospital Cardiac Arrest - therapy
Quality Control
recurrent neural network (RNN)
Recurrent neural networks
Resuscitation
Segments
Signal quality
thoracic impedance
Thorax
Ventilation
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Summary:Feedback on ventilation could help improve cardiopulmonary resuscitation quality and survival from out-of-hospital cardiac arrest (OHCA). However, current technology that monitors ventilation during OHCA is very limited. Thoracic impedance (TI) is sensitive to air volume changes in the lungs, allowing ventilations to be identified, but is affected by artifacts due to chest compressions and electrode motion. This study introduces a novel algorithm to identify ventilations in TI during continuous chest compressions in OHCA. Data from 367 OHCA patients were included, and 2551 one-minute TI segments were extracted. Concurrent capnography data were used to annotate 20724 ground truth ventilations for training and evaluation. A three-step procedure was applied to each TI segment: First, bidirectional static and adaptive filters were applied to remove compression artifacts. Then, fluctuations potentially due to ventilations were located and characterized. Finally, a recurrent neural network was used to discriminate ventilations from other spurious fluctuations. A quality control stage was also developed to anticipate segments where ventilation detection could be compromised. The algorithm was trained and tested using 5-fold cross-validation, and outperformed previous solutions in the literature on the study dataset. The median (interquartile range, IQR) persegment and per-patient F 1 -scores were 89.1 (70.8-99.6) and 84.1 (69.0-93.9), respectively. The quality control stage identified most low performance segments. For the 50% of segments with highest quality scores, the median per-segment and per-patient F 1 -scores were 100.0 (90.9-100.0) and 94.3 (86.5-97.8). The proposed algorithm could allow reliable, quality-conditioned feedback on ventilation in the challenging scenario of continuous manual CPR in OHCA.
ISSN:2168-2194
2168-2208
DOI:10.1109/JBHI.2023.3253780