BreathFinder: A method for non-invasive isolation of respiratory cycles utilizing the thoracic respiratory inductance plethysmography signal
BreathFinder: A method for non-invasive isolation of respiratory cycles utilizing the thoracic respiratory inductance plethysmography signal
INTRODUCTION: The field of automatic respiratory analysis focuses mainly on breath detection on signals such as audio recordings, or nasal flow measurement, which suffer from issues with background noise and other disturbances. Here we introduce a novel algorithm designed to isolate individual respiratory cycles on a thoracic respiratory inductance plethysmography signal using the non-invasive signal of the respiratory inductance plethysmography belts.
PURPOSE: The algorithm locates breaths using signal processing and statistical methods on the thoracic respiratory inductance plethysmography belt and enables the analysis of sleep data on an individual breath level.
PATIENTS AND METHODS: The algorithm was evaluated against a cohort of 31 participants, both healthy and diagnosed with obstructive sleep apnea. The dataset consisted of 13 female and 18 male participants between the ages of 20 and 69. The algorithm was evaluated on 7.3 hours of hand-annotated data from the cohort, or 8782 individual breaths in total. The algorithm was specifically evaluated on a dataset containing many sleep-disordered breathing events to confirm that it did not suffer in terms of accuracy when detecting breaths in the presence of sleep-disordered breathing. The algorithm was also evaluated across many participants, and we found that its accuracy was consistent across people. Source code for the algorithm was made public via an open-source Python library.
RESULTS: The proposed algorithm achieved an estimated 94% accuracy when detecting breaths in respiratory signals while producing false positives that amount to only 5% of the total number of detections. The accuracy was not affected by the presence of respiratory related events, such as obstructive apneas or snoring.
CONCLUSION: This work presents an automatic respiratory cycle algorithm suitable for use as an analytical tool for research based on individual breaths in sleep recordings that include respiratory inductance plethysmography.
1253-1266
Holm, Benedikt
d9ae89eb-36f6-4355-bdf0-90507762c9c5
Borsky, Michal
db9e2da6-e036-4dad-961b-7c964d9c8e88
Arnardottir, Erna S
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Serwatko, Marta
27ae6444-8871-4220-b849-40c1834ab0ca
Mallett, Jacky
9e94903d-8d77-4af2-83b5-f1eda66883cc
Islind, Anna Sigridur
aefc8cda-7d3e-4367-bfca-e9a2261fe87f
Óskarsdóttir, María
d159ed8f-9dd3-4ff3-8b00-d43579ab71be
20 August 2024
Holm, Benedikt
d9ae89eb-36f6-4355-bdf0-90507762c9c5
Borsky, Michal
db9e2da6-e036-4dad-961b-7c964d9c8e88
Arnardottir, Erna S
9bfbbe32-8214-47a9-86ba-43be85458830
Serwatko, Marta
27ae6444-8871-4220-b849-40c1834ab0ca
Mallett, Jacky
9e94903d-8d77-4af2-83b5-f1eda66883cc
Islind, Anna Sigridur
aefc8cda-7d3e-4367-bfca-e9a2261fe87f
Óskarsdóttir, María
d159ed8f-9dd3-4ff3-8b00-d43579ab71be
Holm, Benedikt, Borsky, Michal, Arnardottir, Erna S, Serwatko, Marta, Mallett, Jacky, Islind, Anna Sigridur and Óskarsdóttir, María
(2024)
BreathFinder: A method for non-invasive isolation of respiratory cycles utilizing the thoracic respiratory inductance plethysmography signal.
Nature and Science of Sleep, 16, .
(doi:10.2147/NSS.S468431).
Abstract
INTRODUCTION: The field of automatic respiratory analysis focuses mainly on breath detection on signals such as audio recordings, or nasal flow measurement, which suffer from issues with background noise and other disturbances. Here we introduce a novel algorithm designed to isolate individual respiratory cycles on a thoracic respiratory inductance plethysmography signal using the non-invasive signal of the respiratory inductance plethysmography belts.
PURPOSE: The algorithm locates breaths using signal processing and statistical methods on the thoracic respiratory inductance plethysmography belt and enables the analysis of sleep data on an individual breath level.
PATIENTS AND METHODS: The algorithm was evaluated against a cohort of 31 participants, both healthy and diagnosed with obstructive sleep apnea. The dataset consisted of 13 female and 18 male participants between the ages of 20 and 69. The algorithm was evaluated on 7.3 hours of hand-annotated data from the cohort, or 8782 individual breaths in total. The algorithm was specifically evaluated on a dataset containing many sleep-disordered breathing events to confirm that it did not suffer in terms of accuracy when detecting breaths in the presence of sleep-disordered breathing. The algorithm was also evaluated across many participants, and we found that its accuracy was consistent across people. Source code for the algorithm was made public via an open-source Python library.
RESULTS: The proposed algorithm achieved an estimated 94% accuracy when detecting breaths in respiratory signals while producing false positives that amount to only 5% of the total number of detections. The accuracy was not affected by the presence of respiratory related events, such as obstructive apneas or snoring.
CONCLUSION: This work presents an automatic respiratory cycle algorithm suitable for use as an analytical tool for research based on individual breaths in sleep recordings that include respiratory inductance plethysmography.
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Published date: 20 August 2024
Additional Information:
© 2024 Holm et al.
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Local EPrints ID: 504338
URI: http://eprints.soton.ac.uk/id/eprint/504338
ISSN: 1179-1608
PURE UUID: dce1b08d-3db3-49bd-af03-f337327f3051
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Date deposited: 04 Sep 2025 16:56
Last modified: 16 Sep 2025 02:31
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Author:
Benedikt Holm
Author:
Michal Borsky
Author:
Erna S Arnardottir
Author:
Marta Serwatko
Author:
Jacky Mallett
Author:
Anna Sigridur Islind
Author:
María Óskarsdóttir
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