Assessment of a New Piezoelectric Transducer Sensor for Noninvasive Cardiorespiratory Monitoring of Newborn Infants in the NICU

Sato, Shinichi; Ishida-Nakajima, Wako; Ishida, Akira; Kawamura, Masanari; Miura, Shinobu; Ono, Koichi; Inagaki, Nobuya; Takada, Goro; Takahashi, Tsutomu

doi:10.1159/000283994

Cited by 30 publications

(31 citation statements)

References 57 publications

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“…The detection ratio was higher than expected considering the small dimensions of the piezoelectric sensor. Moreover, no patient complained about the use of the piezoelectric sensor during measurement, consistent with a previous study …”

Section: Resultssupporting

confidence: 90%

“…Hence, a simple device such as single‐signal screening instrument has been desired . We have developed a piezoelectric sensor system that is available for cardiorespiratory monitoring and that uses a single piezoelectric‐sensor signal . The piezoelectric sensor captures vibrations produced by heartbeats and breathing movements and noninvasively converts them into an electrical signal; the sensor never comes into contact with the patient's skin because it is placed under a sheet on a bed.…”

Section: Introductionmentioning

confidence: 99%

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Apnea during Cheyne-Stokes-like breathing detected by a piezoelectric sensor for screening of sleep disordered breathing

Koyama

Sato

Kanbayashi

et al. 2014

Sleep and Biological Rhythms

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A simplified diagnostic/monitoring instrument for use in primary screening for sleep-disordered breathing (SDB) has been desired. This study was designed to assess the validity of a newly developed piezoelectric sensor as a simple and noninvasive tool for primary screening for sleepdisordered breathing. Forty-three consecutive patients suspected of having sleep-disordered breathing and 10 healthy volunteers were enrolled. Breathing movement was detected with the piezoelectric sensor (180 × 30 × 1 mm), which was placed under a bed sheet under patients, and simultaneous polysomnographic recordings were obtained. We counted the number of apneas of >10 s, irrespective of central or obstructive, that appeared during Cheyne-Stokes-like breathing with a waxing and waning pattern with an amplitude ratio of >10 in the piezoelectric sensor signal. The correlation coefficient between the number of apneas and apnea-hypopnea index (AHI) was 0.74 (P < 0.0001). The sensitivity/specificity of the number of apneas for distinguishing non-SDB patients from mild SDB patients (AHI ≥ 5) were 92.1/60.0% and those for separating moderate to severe (AHI ≥ 15) and severe (AHI ≥ 30) SDB patients from the other patients were 96.9/100% and 93.8/86.5%, respectively. There were no complaints from patients about the use of the piezoelectric sensor. The results indicate that the number of apneas detected by this piezoelectric sensor during Cheyne-Stokes-like breathing is a potential new index for primary screening for SDB at least for cardiac patients. Thus, the piezoelectric-sensor system might be useful for simple, noninvasive and comfortable SDB screening at home, hospitals and health care facilities.

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Section: Resultssupporting

confidence: 90%

Section: Introductionmentioning

confidence: 99%

Apnea during Cheyne-Stokes-like breathing detected by a piezoelectric sensor for screening of sleep disordered breathing

Koyama

Sato

Kanbayashi

et al. 2014

Sleep and Biological Rhythms

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“…[5][6][7] The piezoelectric transducer that is part of the accelerometer is useful for detecting cardiac and/or breathing movements when the sensor is placed under the body of small animals or humans. [8][9][10][11] The measurement is achieved by simply placing animals on the piezoelectric sensor and using an ideal high-pass filter to isolate heart sounds from the raw piezoelectric sensor signals. 8,10,11 The signals contain mechanical vibration signals arising from the heart beat, i.e., contraction and relaxation of ventricles, blood ejection, and closing and opening of valves.…”

Section: Introductionmentioning

confidence: 99%

Noninvasive Monitoring of Cardiac Preload and Contractility by Heart Beat-Derived Mechanical Vibration on the Chest Wall in Guinea Pigs

Adachi¹,

Ohba²,

Fujisawa³

et al. 2016

J.ATAMIS

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Background: Myocardial motion produces compression waves that are transmitted to the surface of the chest and vibrate the chest wall. Piezoelectric transducers, which detect mechanical vibrations, may be useful for evaluating cardiac and/or breathing movements when the sensor is placed under an animal’s body.Methods: We assessed heartbeat-related chest vibration signals (CVS) detected with a piezoelectric transducer in anesthetized guinea pigs while simultaneously monitoring the electrocardiogram, heart sounds, aortic pressure, and central venous pressure.Results: CVS displayed characteristic features as the ventricle and/or atrium contracted and relaxed during cardiac cycles. A transient positive wave, which occurred approximately at the onset of the R wave on the electrocardiogram, was followed by a profound negative wave during systole. The negative wave peaked early in systole and then gradually returned. A small notch was observed at the second heart sound. A dome-shaped positive wave was observed during diastole that connected to the transient positive wave of the next cardiac cycle. In response to phlebotomy (blood volume, 15 ml/kg), the size of the dome-shaped positive wave decreased, whereas saline transfusion (20 ml/kg) increased the positive wave during diastole. Administration of isoproterenol markedly increased the transient positive wave at the onset of systole, whereas phenylephrine affected the transient positive wave only slightly.Conclusions: Our findings suggest that CVS may be useful to identify cardiac cycles and to evaluate cardiovascular dynamics during changes in blood volume and/or cardiac contractility.

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“…Patients admitted to Neonatal Intensive Care Units (NICU) require continuous monitoring of physiological parameters such as Respiration Rate (RR) and Heart Rate (HR). Widely used Respiration Rate (RR) monitoring techniques in NICU include Impedance Pneumography (IP) and flow measurement from mechanical ventilation [1], [2]. These invasive techniques are reliable and well-studied [3]- [5].…”

Section: Motivationmentioning

confidence: 99%

“…Pressure-and force-based vital signs monitoring has been an active research area for several years, mainly due to the unobtrusive and non-contact nature of the sensors [1], [17], [18], [23], [24], [37][38] [39].…”

Section: Pressure-based Respiration Rate Measurementmentioning

confidence: 99%

Neonatal Respiratory Rate Monitoring Using a Pressure-Sensitive Mat

Bekele¹

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Pressure measurement using a Pressure Sensitive Mat (PSM) enables a non-contact approach for monitoring patient vital signs such as respiration rate (RR) and heart rate (HR). Non-contact patient monitoring in Neonatal Intensive Care Units (NICU) can improve the quality of patient care and reduce patient discomfort. This thesis investigates the applicability of PSM for monitoring of neonatal patient respiration rate in the NICU.A clinical trial was conducted with the Children's Hospital of Eastern Ontario (CHEO) collecting PSM data from 15 patients in three different bed types. Gold standard RR and annotations of patient movement and interventions were collected simultaneously.Algorithms for estimating RR were developed by optimizing spatial downsampling, reference signal selection, enhancement, and combining. The RR estimation results were evaluated against gold standard estimates from a commercial patient monitor. The best RR estimation method worked well when the patient is on ventilator support achieving a mean absolute error (MAE) of 3.9 +/-6.6 bpm on clean data without patient movements or interventions. For this patient, 89.7% of RR estimates were within the clinically acceptable range of +/-10 bpm, while 78.4% fell within the more stringent limits of +/-5 bpm.When the RR estimation algorithm is evaluated on all patients, RR estimation performance is mixed. In particular, very low mass neonates and patients laying on multiple blankets presented challenges for RR estimation. Taken together, a 95% confidence interval (CI) for agreement between the estimated and gold standard RR was estimated to be [-44.8, 51.9] bpm with a mean bias of 3.5 bpm, using a mixed effects limits of agreement (LoA)

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Assessment of a New Piezoelectric Transducer Sensor for Noninvasive Cardiorespiratory Monitoring of Newborn Infants in the NICU

Cited by 30 publications

References 57 publications

Apnea during Cheyne-Stokes-like breathing detected by a piezoelectric sensor for screening of sleep disordered breathing

Apnea during Cheyne-Stokes-like breathing detected by a piezoelectric sensor for screening of sleep disordered breathing

Noninvasive Monitoring of Cardiac Preload and Contractility by Heart Beat-Derived Mechanical Vibration on the Chest Wall in Guinea Pigs

Neonatal Respiratory Rate Monitoring Using a Pressure-Sensitive Mat

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