Clinical Evaluation of Stretchable and Wearable Inkjet-Printed Strain Gauge Sensor for Respiratory Rate Monitoring at Different Body Postures

Al-Halhouli, Ala’aldeen; Al‐Ghussain, Loiy; Bouri, Saleem El; Habash, Fuad; Liu, Haipeng; Zheng, Dingchang

doi:10.3390/app10020480

Cited by 34 publications

(29 citation statements)

References 37 publications

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“…It has been proven that with a gap longer than 10 min, there was significant difference (>30% of measured value) between repeated measurements of RF ( Edmonds et al, 2002 ). In our parallel study, with the gap of 1 min, there was no significant difference between repeated measurements of RF ( Al-Halhouli et al, 2020 ). Therefore, we used the gap of 2 min to ensure the repeatability of the RF measurements while the subjects could have a good rest.…”

Section: Discussionmentioning

confidence: 55%

Influences of Sensor Placement Site and Subject Posture on Measurement of Respiratory Frequency Using Triaxial Accelerometers

2020

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Introduction Respiration frequency (RF) could be derived from the respiratory signals recorded by accelerometers which detect chest wall movements. The optimum direction of acceleration for accurate RF measurement is still uncertain. We aim to investigate the effect of measure site, posture, and direction of acceleration on the accuracy of accelerometer-based RF estimation. Methods In supine and seated postures respectively, respiratory signals were measured from 34 healthy subjects in 70 s by triaxial accelerometers located at four sites on the body wall (over the clavicle, laterally on the chest wall, over the pectoral part of the anterior chest wall, on the abdomen in the midline at the umbilicus), with the reference respiratory signal simultaneously recorded by a strain gauge chest belt. RFs were extracted from the accelerometer and reference respiratory signals using wavelet transformation. To investigate the effect of measure site, posture, and direction of acceleration on the accuracy of accelerometer-based RF estimation, repeated measures multivariate analysis of variance, linear regression, Bland-Altman analysis, and Scheirer-Ray-Hare test were performed between reference and accelerometer-based RFs. Results There was no significant difference in accelerometer-based RF estimation between seated and supine postures, among four accelerometer sites, or between seated or supine postures ( p > 0.05 for all). The error of accelerometer-based RF estimation was less than 0.03 Hz (two breaths per minute) at any site or posture, but was significantly smaller in supine posture than in seated posture ( p < 0.05), with narrower limits of agreement in Bland-Altman analysis and higher accuracy in linear regression ( R 2 > 0.61 vs. R 2 < 0.51). Conclusion Respiration frequency can be accurately measured from the acceleration of any direction using triaxial accelerometers placed at the clavicular, pectoral and lateral sites on the chest as well the mid abdominal site. More accurate RF estimation could be achieved in supine posture compared with seated posture.

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Section: Discussionmentioning

confidence: 55%

Influences of Sensor Placement Site and Subject Posture on Measurement of Respiratory Frequency Using Triaxial Accelerometers

2020

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“…The sensor technologies include thermal, humidity, acoustic, pressure, resistive, inductive, acceleration, electromyography, and impedance. A wearable device with these sensors can be mounted into chest belts, attached to a chest belt [40][41][42][43], or applied to the skin [44,45], amongst other modes of attachment.…”

Section: B Respiratory Ratementioning

confidence: 99%

“…But monitoring with a face mask can still be intrusive to users, and the displacement of the sensor may affect the accuracy. [47], RespiraSense™ patch (PMD Solutions, Ireland) [48], and MonBaby clip (MonBaby, New York, USA) [49], (b) Zephyr™ garment (Zephyr Technology, Auckland, New Zealand) [50], and state-of-the-art research (c) an epidermal thermal sensor [45], (d) humidity sensor [46], (e) wearable strain gauge [41], (f) waist-wearable triboelectric sensor, (g) breathing belt with 3D accelerometer [42], and (h) a BandAid like respiratory monitor [44].…”

Section: B Respiratory Ratementioning

confidence: 99%

“…The results indicate a high RR estimation accuracy (<0.07±0.54 bpm) at these places without significant difference, but the upper thorax was shown to be the most comfortable location [41]. Zhang et al developed a triboelectric nanogenerator based waist-wearable wireless respiratory monitoring device, and it was demonstrated to be highly accurate and sensitive for realtime respiratory monitoring [40].…”

Section: B Respiratory Ratementioning

confidence: 99%

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Wearable Sensing and Telehealth Technology with Potential Applications in the Coronavirus Pandemic

Ding

Clifton

et al. 2021

IEEE Rev. Biomed. Eng.

205

155

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Coronavirus disease 2019 (COVID-19) has emerged as a pandemic with serious clinical manifestations including death.A pandemic at the large-scale like COVID-19 places extraordinary demands on the world's health systems, dramatically devastates vulnerable populations, and critically threatens the global communities in an unprecedented way. While tremendous efforts at the frontline are placed on detecting the virus, providing treatments and developing vaccines, it is also critically important to examine the technologies and systems for tackling disease emergence, arresting its spread and especially the strategy for diseases prevention. The objective of this article is to review enabling technologies and systems with various application scenarios for handling the COVID-19 crisis. The article will focus specifically on 1) wearable devices suitable for monitoring the populations at risk and those in quarantine, both for evaluating the health status of caregivers and management personnel, and for facilitating triage processes for admission to hospitals; 2) unobtrusive sensing systems for detecting the disease and for monitoring patients with relatively mild symptoms whose clinical situation could suddenly worsen in improvised hospitals; and 3) telehealth technologies for the remote monitoring and diagnosis of COVID-19 and related diseases. Finally, further challenges and opportunities for future directions of development are highlighted.

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“…Al-Halhouli et al. used the inkjet printing technique to develop a stretchable and wearable strain gauge sensor (gauge factor >100) which could accurately measure the respiratory volume change in the chest area at five different postures; this included standing, sitting at 90°, Fowler's position at 45°, supine and right lateral recumbent ( Al-Halhouli et al., 2020 ).…”

Section: Manufacturing Techniques For Flexible Wearable Devicesmentioning

confidence: 99%

Flexible ferroelectric wearable devices for medical applications

et al. 2021

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Clinical Evaluation of Stretchable and Wearable Inkjet-Printed Strain Gauge Sensor for Respiratory Rate Monitoring at Different Body Postures

Cited by 34 publications

References 37 publications

Influences of Sensor Placement Site and Subject Posture on Measurement of Respiratory Frequency Using Triaxial Accelerometers

Influences of Sensor Placement Site and Subject Posture on Measurement of Respiratory Frequency Using Triaxial Accelerometers

Wearable Sensing and Telehealth Technology with Potential Applications in the Coronavirus Pandemic

Flexible ferroelectric wearable devices for medical applications

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