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Literature DB >> 12803287

Neural network for photoplethysmographic respiratory rate monitoring.

Abstract

The reflection mode photoplethysmographic (PPG) signal was studied with the aim of determining respiratory rate. The PPG signal includes respiratory synchronous components, seen as frequency modulation of the heart rate (respiratory sinus arrhythmia), amplitude modulation of the cardiac pulse and respiratory-induced intensity variations (RIIVs) in the PPG baseline. PPG signals were recorded from the foreheads of 15 healthy subjects. From these signals, the systolic wave-form, diastolic waveform, respiratory sinus arrhythmia, pulse amplitude and RIIVs were extracted. Using basic algorithms, the rates of false positive and false negative detection of breaths were calculated separately for each of the five components. Furthermore, a neural network was assessed in a combined pattern recognition approach. The error rates (sum of false positive and false negative breath detections) for the basic algorithms ranged from 9.7% (pulse amplitude) to 14.5% (systolic waveform). The corresponding values for the neural network analysis were 9.5-9.6%. These results suggest the use of a combined PPG system for simultaneous monitoring of respiratory rate and arterial oxygen saturation (pulse oximetry).

Entities: Disease

Mesh：

Year: 2003 PMID： 12803287 DOI： 10.1007/bf02348427

Source DB: PubMed Journal: Med Biol Eng Comput ISSN： 0140-0118 Impact factor: 2.602

21 in total

Neural network for photoplethysmographic respiratory rate monitoring.

1. Long-term registration of cutaneous microcirculation during general anesthesia.

2. Ventilation mode recognition using artificial neural networks.

3. Changes in tidal volume, frequency, and ventilation induced by their measurement.

4. Presentation and evaluation of a new optical sensor for respiratory rate monitoring.

5. Photo-electric plethysmography as a monitoring device in anaesthesia. Application and interpretation.

6. A method for clinical evaluation of peripheral circulation: photoelectric hemodensitometry.

7. Monitoring of heart and respiratory rates in newborn infants using a new photoplethysmographic technique.

8. Monitoring of respiratory rate in postoperative care using a new photoplethysmographic technique.

Review 9. Pulse oximetry: theory and applications for noninvasive monitoring.

10. A system for rapid identification of respiratory abnormalities using a neural network.

1. The use of joint time frequency analysis to quantify the effect of ventilation on the pulse oximeter waveform.

2. Using the morphology of photoplethysmogram peaks to detect changes in posture.

3. Pulse wave transit time for monitoring respiration rate.

4. Evaluating Innovative In-Ear Pulse Oximetry for Unobtrusive Cardiovascular and Pulmonary Monitoring During Sleep.

5. Developing an algorithm for pulse oximetry derived respiratory rate (RR(oxi)): a healthy volunteer study.

6. Identifying airway obstructions using photoplethysmography (PPG).

7. Pulse oximetry-derived respiratory rate in general care floor patients.

8. Fast and Robust Real-Time Estimation of Respiratory Rate from Photoplethysmography.

Review 9. A Review of Deep Learning-Based Contactless Heart Rate Measurement Methods.

10. Estimating respiratory and heart rates from the correntropy spectral density of the photoplethysmogram.