A sleep stage estimation algorithm based on cardiorespiratory signals derived from a suprasternal pressure sensor

Luca Cerina (Corresponding author), Sebastiaan Overeem, Gabriele B. Papini, Johannes P van Dijk, Rik Vullings, Fokke van Meulen, Marco Ross, Andreas Cerny, Peter Anderer, Pedro Fonseca

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Abstract

Automatic estimation of sleep structure is an important aspect in moving sleep monitoring from clinical laboratories to people's homes. However, the transition to more portable systems should not happen at the expense of important physiological signals, such as respiration. Here, we propose the use of cardiorespiratory signals obtained by a suprasternal pressure (SSP) sensor to estimate sleep stages. The sensor is already used for diagnosis of sleep-disordered breathing (SDB) conditions, but besides respiratory effort it can detect cardiac vibrations transmitted through the trachea. We collected the SSP sensor signal in 100 adults (57 male) undergoing clinical polysomnography for suspected sleep disorders, including sleep apnea syndrome, insomnia, and movement disorders. Here, we separate respiratory effort and cardiac activity related signals, then input these into a neural network trained to estimate sleep stages. Using the original mixed signal the results show a moderate agreement with manual scoring, with a Cohen's kappa of 0.53 in Wake/N1-N2/N3/rapid eye movement sleep discrimination and 0.62 in Wake/Sleep. We demonstrate that decoupling the two signals and using the cardiac signal to estimate the instantaneous heart rate improves the process considerably, reaching an agreement of 0.63 and 0.71. Our proposed method achieves high accuracy, specificity, and sensitivity across different sleep staging tasks. We also compare the total sleep time calculated with our method against manual scoring, with an average error of -1.83 min but a relatively large confidence interval of ±55 min. Compact systems that employ the SSP sensor information-rich signal may enable new ways of clinical assessments, such as night-to-night variability in obstructive sleep apnea and other sleep disorders.

Original languageEnglish
Article numbere14015
Number of pages11
JournalJournal of Sleep Research
Volume33
Issue number2
Early online date12 Aug 2023
DOIs
Publication statusPublished - Apr 2024

Funding

This work was supported by grants within the IMPULS framework of the Eindhoven MedTech Innovation Center (e/MTIC, incorporating Eindhoven University of Technology, Philips Research, and Sleep Medicine Center Kempenhaeghe), including a PPS‐supplement from Dutch Ministry of Economic Affairs and Climate Policy. Additional support by STW/IWT in the context of the OSA+ project (No. 14619).

FundersFunder number
Sleep Medicine Centre Kempenhaeghe
Eindhoven University of Technology
Ministerie van Economische Zaken en Klimaat

    Keywords

    • neural networks
    • polysomnography
    • respiratory analysis
    • signal processing
    • sleep
    • sleep-disordered breathing

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