Your search keyword '"Schipper, Fons"' showing total 2 results

1. Estimating the Severity of Obstructive Sleep Apnea Using ECG, Respiratory Effort and Neural Networks

Author

Fonseca, Pedro, Ross, Marco, Cerny, Andreas, Anderer, Peter, Schipper, Fons, Grassi, Angela, van Gilst, Merel, and Overeem, Sebastiaan

Abstract

Objective: wearable sensor technology has progressed significantly in the last decade, but its clinical usability for the assessment of obstructive sleep apnea (OSA) is limited by the lack of large and representative datasets simultaneously acquired with polysomnography (PSG). The objective of this study was to explore the use of cardiorespiratory signals common in standard PSGs which can be easily measured with wearable sensors, to estimate the severity of OSA. Methods: an artificial neural network was developed for detecting sleep disordered breathing events using electrocardiogram (ECG) and respiratory effort. The network was combined with a previously developed cardiorespiratory sleep staging algorithm and evaluated in terms of sleep staging classification performance, apnea-hypopnea index (AHI) estimation, and OSA severity estimation against PSG on a cohort of 653 participants with a wide range of OSA severity. Results: four-class sleep staging achieved a κ of 0.69 versus PSG, distinguishing wake, combined N1-N2, N3 and REM. AHI estimation achieved an intraclass correlation coefficient of 0.91, and high diagnostic performance for different OSA severity thresholds. Conclusions: this study highlights the potential of using cardiorespiratory signals to estimate OSA severity, even without the need for airflow or oxygen saturation (SpO2), traditionally used for assessing OSA. Significance: while further research is required to translate these findings to practical and unobtrusive sensors, this study demonstrates how existing, large datasets can serve as a foundation for wearable systems for OSA monitoring. Ultimately, this approach could enable long-term assessment of sleep disordered breathing, facilitating new avenues for clinical research in this field.

Published

2024

2. A deep-learning approach to assess respiratory effort with a chest-worn accelerometer during sleep.

Author

Schipper, Fons, JG van Sloun, Ruud, Grassi, Angela, Overeem, Sebastiaan, and Fonseca, Pedro

Subjects

CONVOLUTIONAL neural networks, SLEEP stages, PRINCIPAL components analysis, ACCELEROMETERS, DEEP learning

Abstract

[Display omitted] • A chest-worn accelerometer was used by 146 participants during an overnight sleep recording. • A neural network was automatically generated and trained to extract respiratory activity. • Reference and predicted respiratory waveforms were automatically aligned. • The estimation error was halved compared to Principal Component Analysis. • Differences in the respiratory signal between sleep stages could be reproduced. The objective is to develop a new deep learning method for the estimation of respiratory effort from a chest-worn accelerometer during sleep. We evaluate performance, compare it against a state-of-the art method, and assess whether it can differentiate between sleep stages. In 146 participants undergoing overnight polysomnography data were collected from an accelerometer worn on the chest. The study data were partitioned into train, validation, and holdout (test) sets. We used the train and validation sets to generate and train a convolutional neural network and performed model selection respectively, while we used the holdout set (72 participants) to evaluate performance. A convolutional neural network with 9 layers and 207,855 parameters was automatically generated and trained. The neural network significantly outperformed the best performing conventional method, based on Principal Component Analysis; it reduced the Mean Squared Error from 0.26 to 0.11 and it also performed better in the detection of breaths (Sensitivity 98.4 %, PPV 98.2 %). In addition, the neural network exposed significant differences in characteristics of respiratory effort between sleep stages (p < 0.001). The deep learning method predicts respiratory effort with low error and is sensitive and precise in the detection of breaths. In addition, it reproduces differences between sleep stages, which may enable automatic sleep staging, using just a chest-worn accelerometer. [ABSTRACT FROM AUTHOR]

Published

2023