Apnea and heart rate detection from tracheal body sounds for the diagnosis of sleep-related breathing disorders

Kalkbrenner, Christoph; Eichenlaub, Manuel; Rüdiger, S; Kropf-Sanchen, Cornelia; Rottbauer, Wolfgang; Brucher, Rainer

doi:10.1007/s11517-017-1706-y

Cited by 27 publications

(20 citation statements)

References 25 publications

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“…But their study detects also heartbeats and movements which gives a more complete monitoring. A more recent study of the same group [9] advance in result with a sensitivity of 92.8% and a specificity of 99.7%. But this algorithm, based on temporal domain with 3 envelopes, needs to scan the entire recording, so it cannot be applied in real-time, and is not adapted to phrenic stimulation system monitoring.…”

Section: Fig 7: Detection Results With Speech and Background Noisesmentioning

confidence: 85%

Breathing detection from tracheal sounds in both temporal and frequency domains in the context of phrenic nerve stimulation

Guiraud

Renaux³

et al. 2019

2019 41st Annual International Conference of the IEEE Engineering in Medicine and Biology Society (EMBC)

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Electrical stimulation of the phrenic nerves via implanted devices allows to counteract some disadvantages of mechanical ventilation in patients with high tetraplegia or Ondine's syndrome. Existing devices do not allow to monitor breathing or to adapt the electroventilation to patients' actual needs. A reliable breathing monitor with an inbuilt alarm function would improve patient safety. In our study, a realtime acoustic breathing detection method is proposed as a possible solution to improve implanted phrenic stimulation. A new algorithm to process tracheal sounds has been developed. It combines breathing detection in both temporal and frequency domains. The algorithm has been applied on recordings from 18 healthy participants. The obtained average sensitivity, specificity and accuracy of the detection are: 99.31%, 96.84% and 98.02%, respectively. These preliminary results show a first positive proof of the interest of such an approach. Additional experiments are needed, including longer recordings from individuals with tetraplegia or Ondine Syndrome in various environments to go further in the validation.

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Section: Fig 7: Detection Results With Speech and Background Noisesmentioning

confidence: 85%

Breathing detection from tracheal sounds in both temporal and frequency domains in the context of phrenic nerve stimulation

Guiraud

Renaux³

et al. 2019

2019 41st Annual International Conference of the IEEE Engineering in Medicine and Biology Society (EMBC)

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“…It can therefore be assumed that the new sleep monitor can be used for simple sleep monitoring and preliminary screening at home. Additionally, previous research proved that the new sleep monitor is also able to diagnose one of the most common sleep disorders OSA [ 19 ], [ 20 ]. Using sleep staging, it is suggested that the monitor can now also be used to diagnose other sleep disorders, such as insomnia, or for a preliminary screening to decide whether a PSG is necessary or not.…”

Section: Discussionmentioning

confidence: 99%

“…This curve can now easily be used to detect breathing cycles and estimate airflow. A broader discussion of the challenges of relating the amount of airflow to tracheal breathing sounds can be found in [ 20 ], [ 31 ], [ 32 ]. With this information, the respiratory features presented in Table 2 (Tab.…”

Section: Methodsmentioning

confidence: 99%

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Automated sleep stage classification based on tracheal body sound and actigraphy

Kalkbrenner

Brucher

Kesztyüs³

et al. 2019

GMS German Medical Science; 17:Doc02

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“…Moreover, an attachment of multiple sensors could potentially be inconvenient during sleep. Various contactless technologies were explored for overnight respiratory rate and/or heart rate monitoring including applications of radar [24], WiFi [25], audio recording [26], [27], pressure sensors [28], depth cameras [29], thermal cameras [30], and infrared cameras [31].…”

Section: Introductionmentioning

confidence: 99%

Vision-Based Heart and Respiratory Rate Monitoring During Sleep – A Validation Study for the Population at Risk of Sleep Apnea

Zhu

Akbarian

et al. 2019

IEEE J. Transl. Eng. Health Med.

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A reliable, accessible, and non-intrusive method for tracking respiratory and heart rate is important for improving monitoring and detection of sleep apnea. In this study, an algorithm based on motion analysis of infrared video recordings was validated in 50 adults referred for clinical overnight polysomnography (PSG). The algorithm tracks the displacements of selected feature points on each sleeping participant and extracts respiratory rate using principal component analysis and heart rate using independent component analysis. For respiratory rate estimation (mean ± standard deviation), 89.89 % ± 10.95 % of the overnight estimation was accurate within 1 breath per minute compared to the PSG-derived respiratory rate from the respiratory inductive plethysmography signal, with an average root mean square error (RMSE) of 2.10 ± 1.64 breaths per minute. For heart rate estimation, 77.97 % ± 18.91 % of the overnight estimation was within 5 beats per minute of the heart rate derived from the pulse oximetry signal from PSG, with mean RMSE of 7.47 ± 4.79 beats per minute. No significant difference in estimation of RMSE of either signal was found according to differences in body position, sleep stage, or amount of the body covered by blankets. This vision-based method may prove suitable for overnight, non-contact monitoring of respiratory rate. However, at present, heart rate monitoring is less reliable and will require further work to improve accuracy.

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Apnea and heart rate detection from tracheal body sounds for the diagnosis of sleep-related breathing disorders

Cited by 27 publications

References 25 publications

Breathing detection from tracheal sounds in both temporal and frequency domains in the context of phrenic nerve stimulation

Breathing detection from tracheal sounds in both temporal and frequency domains in the context of phrenic nerve stimulation

Automated sleep stage classification based on tracheal body sound and actigraphy

Vision-Based Heart and Respiratory Rate Monitoring During Sleep – A Validation Study for the Population at Risk of Sleep Apnea

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