Video-Based Physiologic Monitoring During an Acute Hypoxic Challenge: Heart Rate, Respiratory Rate, and Oxygen Saturation

Smit

et al. 2019

Self Cite

Respiratory rate is a well-known to be a clinically important parameter with numerous clinical uses including the assessment of disease state and the prediction of deterioration. It is frequently monitored using simple spot checks where reporting is intermittent and often prone to error. We report here on an algorithm to determine respiratory rate continuously and robustly using a non-contact method based on depth sensing camera technology. The respiratory rate of 14 healthy volunteers was studied during an acute hypoxic challenge where blood oxygen saturation was reduced in steps to a target 70% oxygen saturation and which elicited a wide range of respiratory rates. Depth sensing data streams were acquired and processed to generate a respiratory rate (RR depth). This was compared to a reference respiratory rate determined from a capnograph (RR cap). The bias and root mean squared difference (RMSD) accuracy between RR depth and the reference RR cap was found to be 0.04 bpm and 0.66 bpm respectively. The least squares fit regression equation was determined to be: RR depth = 0.99 × RR cap + 0.13 and the resulting Pearson correlation coefficient, R, was 0.99 (p < 0.001). These results were achieved with a 100% reporting uptime. In conclusion, excellent agreement was found between RR depth and RR cap. Further work should include a larger cohort combined with a protocol to further test algorithmic performance in the face of motion and interference typical of that experienced in the clinical setting.

Section: Introductionmentioning

confidence: 99%

Continuous respiratory rate monitoring during an acute hypoxic challenge using a depth sensing camera

Smit

et al. 2019

Self Cite

“…A concordance value is then computed by calculating the percentage of points lying in the quadrants where both parameters have the same sign, (i.e. both positive or both negative), which indicates co-trending behaviour [24]. Matlab (R2018b) was used to process the data and perform the statistical analysis.…”

Section: Discussionmentioning

confidence: 99%

Continuous non‐contact respiratory rate and tidal volume monitoring using a Depth Sensing Camera

Smit

et al. 2021

Self Cite

The monitoring of respiratory parameters is important across many areas of care within the hospital. Here we report on the performance of a depth-sensing camera system for the continuous non-contact monitoring of Respiratory Rate (RR) and Tidal Volume (TV), where these parameters were compared to a ventilator reference. Depth sensing data streams were acquired and processed over a series of runs on a single volunteer comprising a range of respiratory rates and tidal volumes to generate depth-based respiratory rate (RRdepth) and tidal volume (TVdepth) estimates. The bias and root mean squared difference (RMSD) accuracy between RRdepth and the ventilator reference, RRvent, across the whole data set was found to be -0.02 breaths/min and 0.51 breaths/min respectively. The least squares fit regression equation was determined to be: RRdepth = 0.96 × RRvent + 0.57 breaths/min and the resulting Pearson correlation coefficient, R, was 0.98 (p < 0.001). Correspondingly, the bias and root mean squared difference (RMSD) accuracy between TVdepth and the reference TVvent across the whole data set was found to be − 0.21 L and 0.23 L respectively. The least squares fit regression equation was determined to be: TVdepth = 0.79 × TVvent—0.01 L and the resulting Pearson correlation coefficient, R, was 0.92 (p < 0.001). In conclusion, a high degree of agreement was found between the depth-based respiration rate and its ventilator reference, indicating that RRdepth is a promising modality for the accurate non-contact respiratory rate monitoring in the clinical setting. In addition, a high degree of correlation between depth-based tidal volume and its ventilator reference was found, indicating that TVdepth may provide a useful monitor of tidal volume trending in practice. Future work should aim to further test these parameters in the clinical setting.

“…The home environment is another area of interest as more monitoring is taking place in order to reduce costs and improve out-of-hospital care. In addition, the monitoring of heart rate using video methods may be combined with other video monitoring technologies relevant to the clinical environment, including the monitoring of oxygen saturation [ 8 , 24 ], respiratory rate [ 25 ], pulse transit times [ 26 ], gait, [ 27 ] and the detection of falls [ 28 ]. Further development of video-based physiological monitoring will require robust algorithms to tackle motion and lighting effects before the technology is mature enough for these application areas.…”

Section: Discussionmentioning

confidence: 99%

“…A variety of powerful signal processing methods has been proposed to determine heart rate from the video-PPG. These include frequency-based methods such as spectral peak tracking [ 8 ], and Fourier-based amplitude spectrum and phase spectrum adaptive filter for motion compensation [ 9 ]; wavelet transform time–frequency methods including the weighted transform component method [ 10 ], a dual tree complex wavelet transform method [ 11 ] and a running wavelet archetyping (RWA) method [ 12 ]; independent component analysis (ICA) methods such as the temporal constrained ICA and adaptive filter method [ 13 ], an assessment of three different ICA methods [ 14 ] and a comparison of independent component analysis, principle component analysis (PCA) and cross-correlation [ 15 ].…”

Section: Introductionmentioning

confidence: 99%

Video-based heart rate monitoring across a range of skin pigmentations during an acute hypoxic challenge

Foo

et al. 2017

Self Cite

The robust monitoring of heart rate from the video-photoplethysmogram (video-PPG) during challenging conditions requires new analysis techniques. The work reported here extends current research in this area by applying a motion tolerant algorithm to extract high quality video-PPGs from a cohort of subjects undergoing marked heart rate changes during a hypoxic challenge, and exhibiting a full range of skin pigmentation types. High uptimes in reported video-based heart rate (HRvid) were targeted, while retaining high accuracy in the results. Ten healthy volunteers were studied during a double desaturation hypoxic challenge. Video-PPGs were generated from the acquired video image stream and processed to generate heart rate. HRvid was compared to the pulse rate posted by a reference pulse oximeter device (HRp). Agreement between video-based heart rate and that provided by the pulse oximeter was as follows: Bias = − 0.21 bpm, RMSD = 2.15 bpm, least squares fit gradient = 1.00 (Pearson R = 0.99, p < 0.0001), with a 98.78% reporting uptime. The difference between the HRvid and HRp exceeded 5 and 10 bpm, for 3.59 and 0.35% of the reporting time respectively, and at no point did these differences exceed 25 bpm. Excellent agreement was found between the HRvid and HRp in a study covering the whole range of skin pigmentation types (Fitzpatrick scales I–VI), using standard room lighting and with moderate subject motion. Although promising, further work should include a larger cohort with multiple subjects per Fitzpatrick class combined with a more rigorous motion and lighting protocol.