Respiratory rate estimation from multi-channel signals using auto-regulated adaptive extended Kalman filter

Gupta, Nishant; Simmen, Patrizia; Trachsel, Daniel; Haeberlin, Andreas; Jost, Kerstin; Niederhauser, Thomas (2023). Respiratory rate estimation from multi-channel signals using auto-regulated adaptive extended Kalman filter Biomedical Signal Processing and Control, 84, p. 104977. Elsevier 10.1016/j.bspc.2023.104977

Preview

Text 1-s2.0-S174680942300410X-main-2.pdf - Published Version Available under License Creative Commons: Attribution (CC-BY). Download (3MB) | Preview

Background: Respiration rate (RR) is a major cause for false alarms in intensive care units (ICU) and is primarily impaired by the artifact prone signals from skin-attached electrodes. Catheter-integrated esophageal electrodes are an alternative source for multi-channel physiological signals from multiple organs such as the heart and the diaphragm. Nonlinear estimation and sensor fusion are promising techniques for extracting the respiratory activity from such multi-component signals, however, pathologic breathing patterns with rapid RR changes typically observed in patient populations such as premature infants, pose significant challenges. Methods: We developed an auto-regulated adaptive extended Kalman filter (AA-EKF), which iteratively adapts the system model and the noise parameters based on the respiratory pattern. AA-EKF was tested on neonatal esophageal observations (NEO), and also on simulated multi-components signals created using waveforms in CapnoBase and ETNA databases. Results: AA-EKF derived RR (RRAA-EKF) from NEO had lower median (inter-quartile range) error of 0.1 (10.6) breaths per minute (bpm) compared to contemporary neonatal ICU monitors (RRNICU): −3.8 (15.7) bpm (p <0.001). RRAA-EKF error of −0.2 (3.2) bpm was achieved for ETNA wave forms and a bias (95% LOA) of 0.1 (−5.6, 5.9) in breath count. Mean absolute error (MAE) of RRAA-EKF with Capnobase waveforms, as median (inter-quartile range), at 0.3 (0.2) bpm was comparable to the literature reported values. Discussion: The auto-regulated approach allows RR estimation on a broad set of clinical data without requiring extensive patient specific adjustments. Causality and fast response times of EKF based algorithms makes the AA-EKF suitable for bedside monitoring in the ICU setting.

Item Type:	Journal Article (Original Article)
Division/Institute:	School of Engineering and Computer Science > Institute for Human Centered Engineering (HUCE) School of Engineering and Computer Science > Institute for Human Centered Engineering (HUCE) > HUCE / Laboratory for Microelectronics and Medical Devices School of Engineering and Computer Science BFH Centres and strategic thematic fields > BFH centre for Health technologies
Name:	Gupta, Nishant; Simmen, Patrizia; Trachsel, Daniel; Haeberlin, Andreas; Jost, Kerstin and Niederhauser, Thomas0000-0003-2633-0844
Subjects:	R Medicine > RJ Pediatrics T Technology > TA Engineering (General). Civil engineering (General)
ISSN:	1746-8094
Publisher:	Elsevier
Language:	English
Submitter:	Thomas Niederhauser
Date Deposited:	07 Jun 2023 08:53
Last Modified:	11 Jun 2023 01:37
Publisher DOI:	10.1016/j.bspc.2023.104977
Related URLs:	https://www.sciencedirect.com/journal/bi...
Uncontrolled Keywords:	Respiration rate Sensor fusion Kalman filters Neonates NICU Esophagus
ARBOR DOI:	10.24451/arbor.19294
URI:	https://arbor.bfh.ch/id/eprint/19294